MULTIPLIER PRODUCTS Table of Contents Technical Overview

Back to Mixer Home Page

Application Notes

Quick Reference

Detailed Data Sheets

Higher-Order Active Assem.Higher-Order Assem.

Outline Drawings

100 Davids Drive • Hauppauge, NY 11788 • 631-436-7400 • Fax: 631-436-7430 • www.miteq.com TABLE OF CONTENTS

CONTENTS CONTENTS INTRODUCTIONCONTENTS IMAGE REJECTION/IQ DETECTOR Corporate Overview AND LOW NOISE FRONT-ENDS (CONT.) Technology Overview Low-Noise Image Rejection MULTIPLIERSSpecification Definitions Downconverter Assemblies QualityIntroduction Assurance General Information MTBFTechnical Calculations Overview Mixer Terminology Manufacturing Flow Diagrams Technical Discussion Image Rejection Mixer, I/Q, Device 883 Screening Design Example QIFM Circuits General Specifications Application-Driven Mixer Circuits Space-QualifiedSpecification Definitions Mixers Questions and Answers Defining Multiplier Terms Image Rejection Mixers/QIFMs MIXERS Typical Block Diagrams LNA, Image Rejection Mixers Application Guidelines Specifications and Typical Values BPSK and QPSK Phase Detectors Quick Reference Technical Article EnvironmentalSingle-, Double-Balanced Conditions and Mixer Extended Dynamic Range Mixers Percentagewith IF Amplifier Bandwidth, Rejection and Size Ordering Information ActiveDouble-Balanced, Frequency Biasable,Multipliers CommonTriple-Balanced Applications and MESFET Mixers MODULATORS QuickSub-Harmonic Reference and Specialty Mixers Application Guidelines Detailed Data Sheets Quick Reference DoublePassive Balanced Frequency Ð With Doublers IF Amplifiers Biphase Modulators and DSB Upconverters DoubleActive BalancedFrequency Ð Ultra Doublers Broadband QPSK and QAM Modulators DoubleSelect BalancedBandwidth Ð High Doublers Isolation and Triplers SSB Upconverters and Vector Double-BalancedActive Frequency Ð Wide Triplers IF Bandwidth Modulators/Phase Shifters Double-BalancedHigh Order Active Ð Surface Multipliers Mount Detailed Data Sheets TripleComb Balanced Multiplier Designs Biphase Modulators and DSB Upconverters Biasable Ð Low LO Power QPSK and Modulation Driven Modulators Detailed Data Sheets MESFET Ð High Dynamic Range SSB Upconverters EvenPassive Harmonic Frequency Ð 1/2 LO Doublers Carrier Driven ActiveOctave Multiplier Bandwidth Mixer General Information WaveguideMillimeter Mixer Terminology LO MultioctaveAmplified Bandwidth Modulator Circuit Description in SamplingDrop-In Mixer Order of Complexity General Information Active Frequency Doublers Modulators and Upconverters Double-Sideband Mixer Circuits Questions and Answers Double-SidebandNarrow and Octave Mixer Subsystems Bandwidth Technical Application QuestionsDrop-In and Answers High-Isolation Modulators BalancedMillimeter Schottky Diode Mixers and High-Level Mixers for MESFETMultioctave Mixers Bandwidth Communications Links TechnicalMillimeter Article Ordering Information Fundamental,Active Multiplier Harmonic Assemblies and Sampling MESFET Mixer Circuits MULTIPLIERS TechnicalX2 Application Introduction OrderingMillimeter Information Technical Overview X3 Technical Discussion IMAGE REJECTION/IQ DETECTOR Millimeter Design Example AND LOW NOISE FRONT ENDS Specification Definitions X4 Application Guidelines Defining Multiplier Terms Quick ReferenceMillimeter Typical Block Diagrams ImageX5 Rejection Mixers and Specifications and Typical Values HigherI/Q Demodulators Order Multiplication (X20) Environmental Conditions Low-NoiseSRD Comb Image Generator Rejection Downconverter Percentage Bandwidth, Rejection and Size HigherAssemblies Order and Multiplication I/Q Demodulators (X4) Active Frequency Multipliers Detailed Data Sheets Outline Drawings Common Applications Image Rejection Mixers and I/Q Demodulators Quick Reference EnhancedPassive MultipliersImage Rejection Mixers Passive Frequency Doublers ActiveBiasable Multipliers Image Rejection Mixers Active Frequency Doublers I/QPassive Phase MultipliersDetector with Optional Select Bandwidth Doublers and Triplers QuestionsVideo Amps and and/orAnswers Digital Output Active Frequency Triplers Image Rejection Mixers with High Order Active Multipliers Integrated IF Amplifiers Comb Multiplier Designs INTRODUCTION

This section is intended to provide an overview of suppression as required in many frequency source MITEQ's passive and active multiplier capabilities. applications by employing special filter technologies. Within this catalog you will find a variety of standard designs which will meet typical applications. However, In addition to custom-filter designs, MITEQ also has MITEQ maintains dedicated engineering resources to advanced amplifier technologies which, when com- modify these standard designs in support of custom- bined with balanced multiplier designs, offer high per- generated specifications that are typically required in formance active multipliers especially in the areas of stringent system applications. These critical require- shaped frequency response and desired output levels. ments often require high spectral purity. MITEQ can obtain high levels of fundamental and spurious signal

TECHNICAL OVERVIEW

Most of MITEQ’s frequency multiplier designs perform to specific customer requirements and cannot easily be cat- egorized into standard products. Parameters such as frequency range, bandwidth, spurious rejection and multiplication ratios are normally determined by specific system requirements. These requirements, in turn, translate into custom-designed filter and amplifier specifications at the multiplier design level.

In most frequency multiplier designs, the multiplier output contains, besides the desired harmonic output, unwanted signals. These unwanted signals consist of the fundamental input signal leakage, and lower-order and higher-order harmonics generated in the multiplier. Quite often with odd-order multipliers, the undesired signals are higher in level than the desired signal. In even-order multipliers, the undesired outputs are normally 10 to 20 dB below the desired output. Thus, the output signals can be amplified before the output is filtered. This is not possible with odd-order multipliers because the unwanted signals will cause the amplifier to saturate and suppress the desired output.

Definitions of key performance parameters vary from manufacturer to manufacturer. Some of the variations are minor, while others can lead to misinterpretations of specifications. In order to avoid that problem and facilitate the

TIPLIER PRODUCTS use of this catalog, we have supplied a technical discussion for our series of passive and active multipliers. MUL

375 TECHNICAL DISCUSSION

MULTIPLIER LOSSES The basic multiplier losses of MITEQ’s passive multipliers are listed below; times two (X 2): 12 dB typical times three (X 3): 17 dB typical times four (X 4): 22 dB typical times five (X 5): 23 dB typical

MITEQ’s active multipliers are formed by cascading a passive multiplier and an active device, such as an amplifier. Multipliers of higher orders are formed by cascading these basic blocks. The most common higher-order multiplier used for MITEQ’s systems applications is the times six, which is formed with the cascade of times two and times three. MITEQ manufactures C-band through Ku-band multipliers with built-in comb bandpass filters, MMIC amplifiers and higher-order assemblies that include various combinations of even- and odd-harmonic multipliers.

PHASE NOISE MITEQ multipliers add phase noise to a lower frequency source by approximately 20 x log [N] + 3 dB, where N is the multiplication factor. If spurious products are present on an incoming signal, they increase in level by this factor. Below is a visual representation of this phenomenon:

desired signal desired signal -60 dBc The phase noise contribution -47.5 dBc of the tripler is 12.50 dB; spurious spurious input port of multiplier output port of multiplier

One method of measuring the phase noise contribution is referred to as a residual phase noise measurement and MUL requires three multipliers (three measurements with two multipliers each), so that the source noise is cancelled. At pre- TIPLIER PRODUCTS sent, all of our multipliers have not been thoroughly characterized for phase noise contribution.

SPURIOUS AND HARMONIC REJECTION The concepts of harmonic rejection and spurious rejection are very important in the manufacture of multipliers. An important tool in the design process relates to the spurious-free bandwidth, which can be mathematically calculated from the relation: [N + 1] / N < = [upper frequency limit/lower frequency limit] where N is the multiplication factor. For a tripler, this ratio becomes 4/3 = 1.333. A tripler whose output is 4 to 8 GHz wide has inband spurious outputs that are not filtered because 8/4 = 2, which exceeds the spurious-free bandwidth ratio. With regard to spurious rejection, it makes a difference over what output region the rejection is required. Generally, MITEQ produces multipliers with -65 dBc minimum spurious rejection not only in the output passband, but also out- side the desired passband from (1 to 18 GHz). Spurious outputs take three basic forms. CASE 1. The spurs are not harmonically related to the input and are called nonharmonically-related spurs [not related to N at all].

CASE 2. The spurs are related somehow to the input, or multiples of it, and are called harmonically-related spurious. [N + 1, N - 1, N + 2, etc.].

CASE 3. The spurs are related to multiples of the output and are referred to as output harmonics [N, 3N, 4N, etc.].

At MITEQ, we refer to the first two cases under the general term spurious rejection and to case three by the term output harmonics. Rejection to output harmonics for the vast majority of MITEQ multipliers lies between -15 and -20 dBc. The reason for this is because those multipliers that require amplification usually employ an amplifier that is run in a saturated mode to minimize output power variations versus temperature.

This leads to a key design concept about properly assessing the choice of multiplication factor, and more importantly, how much rejection is required to meet your overall system requirements. The multiplier can be used as part of a synthesizer or source that feeds one port of a mixer. When the spurs of the multiplier enter the mixer, they mix with the RF and its harmonics to produce various unwanted signals that cannot be filtered in the IF passband.

376 DESIGN EXAMPLE

Your system requires a multiplier output from 8.6 to 10.5 GHz. Due to the available input frequencies, it is determined that the multiplication factor is six times. This is best accomplished by cascading a times three and a times two multiplier. The input required for the tripler will be 1433 to 1750 MHz. Multiples of the input, present at the output are: X 2 2866 – 3500 MHz X 3 4299 – 5250 MHz [desired] X 4 5732 – 7000 MHz X 5 7165 – 8750 MHz etc... Suppose that the times five spectral component at the output is not suppressed properly. If your system specification is -70 dBc spurious, for example, and the N + 2 product is only suppressed by -58 dBc, the times six chain will not meet specification, because the next doubler will not provide any additional suppression. This product is an inband spurious because anything from 8600 to 10500 MHz is inband. Suppose, next, that the N + 1 product of the tripler is not suppressed -70 dBc. The desired input to the doubler is 4299 to 5250 MHz, but we also have an input from 5732 to 7000 MHz that was not adequately suppressed. Therefore, we will observe an undesired output from the doubler at the following frequency: N + 1 5732 – 7000 MHz N 4299 – 5250 MHz, the difference product is 1433 – 1750 MHz Since our desired output is 8600 to 10500 MHz, the difference product maps into the region (8600 to 10500 MHz) + (1433 to 1750 MHz) and the result is 10033 to 12250 MHz, which is an undesired product, from at least the 10033 to 10500 MHz region of the desired output passband. The point of this example is to show that when a multiplier system is designed from cascaded multipliers, potential problems exist if you buy the individual multipliers separately from MITEQ and do not take into account all the multiples and their products formed at various stages. MITEQ provides custom-designed higher-order multipliers that will not suffer from these effects.

SPECIFICATION DEFINITIONS TIPLIER PRODUCTS PASSIVE MULTIPLIERS

MUL OUTPUT HARMONIC REJECTION CONVERSION LOSS (also known as multiplier loss) The difference in dB between the desired output and This is the attenuation in dB between the input level harmonics of the output frequency. and the output level. COMMON DEFINITIONS FOR BOTH HARMONIC REJECTION PASSIVE AND ACTIVE MULTIPLIERS The difference in dB between the desired harmonic and OUTPUT POWER FLATNESS the unwanted harmonic as viewed at the multiplier output port. When the unwanted harmonic is the fun- The maximum power variation in dB over a specified damental itself, then the difference is the fundamental frequency and at a specific temperature. rejection. INPUT POWER ACTIVE MULTIPLIERS The level in dBm as measured at the multiplier's input CONVERSION GAIN port.

The net increase in power between the fundamental OUTPUT POWER input signal and the desired output. It is usually ex- pressed as a positive ratio in dB. The level in dBm as measured at the output port of the multiplier. SPURIOUS REJECTION OPERATING TEMPERATURE The difference in dB between the desired output harmonic and any other harmonic as viewed at the multi- The temperature range at which the device meets the plier's output. The spurs can be multiples of the input specified electrical parameters. The temperature is frequency. defined as the base plate temperature of the device.

377 DEFINING MULTIPLIER TERMS

MULTIPLIER INPUT PORT OUTPUT PORT X

INPUT PORT OUTPUT PORT M (Desired Signal N = X Times M to Multiply)

2M 2N N-1 N+1 3N QR 3M Z Y

Input harmonics feeding multiplier = 2M, 3M Output harmonics from multiplier = 2N, 3N Spurious feeding multiplier = Q, R Input harmonic rejection (products generated in the multiplier) = N + 1, N - 1 related to the input Spurious rejection = Y, Z MUL TIPLIER PRODUCTS TYPICAL BLOCK DIAGRAMS

The basic use of frequency multipliers is to extend the output frequency range or bandwidth of a source by multiply- ing that frequency by a given multiplication factor, i.e., twice the fundamental of a 5 to 10 GHz source would yield a 10 to 20 GHz output. The following block diagrams represent but a small sampling of the uses for both passive and active multipliers.

PASSIVE MULTIPLIERS

EVEN ORDER X

ODD ORDER LOWPASS BANDPASS X FILTER FILTER

ACTIVE MULTIPLIERS

EVEN ORDER BANDPASS X AMP FILTER (OPTIONAL)

ODD ORDER BANDPASS LOWPASS X AMP FILTER FILTER

378 TYPICAL BLOCK DIAGRAMS (CONT.)

TIMES 2 MULTIPLIER WITH SOURCE

16 – 20 GHz 4 – 8 GHz

12 GHz @ +13 dBm

AMP

2 X

6 GHz DRO @ +13 dBm

SUBSYSTEM WITH MULTIPLIERS TIPLIER PRODUCTS MUL IMAGE LOWPASS 16 – 20 GHz LIMITER AMPFILTER FILTER IF AMP 4 – 8 GHz

12 GHz @ +13 dBm

AMP

BANDPASS FILTER

X 2

18 GHz

BANDPASS POWER FILTER X 3 SWITCH DIVIDER

TTL

6 GHz DRO @ +13 dBm

379 MULTIPLIER PRODUCTS 380 to discuss the details about specifying the spurious rejec- ENVIRONMENTAL CONDITIONS ENVIRONMENTAL SPECIFICATIONMultiplication factorPhase noise contributionOutput bandwidthInput power [N] + 3 dB 20 log Output power VALUE TYPICAL ratio spurious-free bandwidth Examine Output power flatnessSpurious rejectionOutput harmonics bandwidth ratio Examine spurious-free Operating temperature dB ±1.50 Size +10 dBm +10 dBm -50 to -60 dBc for designs with filters 0 to 50°C -15 dBc Depends on required rejection SPECIFICATIONS AND TYPICAL VALUES TYPICAL AND SPECIFICATIONS Contact MITEQ at (631) 439-9220 PERCENTAGE BANDWIDTH, REJECTION AND SIZE BANDWIDTH, PERCENTAGE Multiplier Percentage Bandwidth = [Output Bandwidth] / [Operating Frequency] Multiplier Percentage Bandwidth = [Output 15 percent bandwidths. MITEQ produces designs with 10 to Bandwidth Ratio = [Reject Frequency - Center Frequency] / [Output Bandwidth] the higher the number the better. Generally, tion and size of your multiplier requirement for a cost-effective design. tion and size of your multiplier requirement for a cost-effective Since the filter is often the largest component of the multiplier, it is useful to know how many resonators are needed it is Since the filter is often the largest component of the multiplier, available to help you get a feel for how large and how large your multiplier might be. MITEQ has engineering support your multiplier might be. When the percentage bandwidth gets too large, and/or when the bandwidth ratio gets too small, the multiplier becomes When the percentage bandwidth gets too large, and/or when the bandwidth to produce and may become quite large because the filtering requirements are forcing the number of filtering difficult frequency. elements to increase. It is also true that the size is related to the operating The last topic to address is perhaps the most complicated. It relates to having some feel for how large a multiplier will the most complicated. It relates to having some feel for how large a multiplier The last topic to address is perhaps which have diagnostic tools used at MITEQ are presented here, Two rejection. be in order to achieve proper spurious played an important role in this regard: MITEQ's standard frequency multipliers have been designed to meet the following environmental conditions: MITEQ's standard frequency multipliers Operating temperature ...... -30 to +75°C Storage temperature ...... -40 to +85°C Humidity ...... noncondensing 95% relative humidity, Vibration ...... 50-5000 CPS, per MIL-STD-810B, Method 514, Procedure 5 rms, 7 g’s Data curves are at 25°C ...... as a function of temperature There will be some variation in the typical data shown One very common problem MITEQ’s customers face when purchasing multipliers is not knowing what specifications multipliers is not when purchasing customers face MITEQ’s common problem One very products. large, bulky and expensive causes that over specification also not appreciating realizable, and are practically here as a reference: values established some practical be overcome by using This can ACTIVE FREQUENCY MULTIPLIERS

TYPICAL PERFORMANCE VS. INPUT POWER INPUT RETURN LOSS VS. INPUT POWER INPUT RETURN LOSS VS. INPUT POWER FOR J DRIVE LEVEL MULTIPLIERS FOR M DRIVE LEVEL MULTIPLIERS 0 0

4 4

8 8

12 12

16 16 RETURN LOSS (dB) RETURN LOSS (dB) 20 20 2 6 10 14 18 22 2 6 10 14 18 22 INPUT POWER (dBm) INPUT POWER (dBm) INPUT RETURN LOSS VS. INPUT POWER OUTPUT VS. INPUT POWER LEVEL FOR V DRIVE LEVEL MULTIPLIERS FOR M AND V DRIVE LEVEL MULTIPLIERS 0 20 V 4 16

8 12 M 12 8

16 4 RETURN LOSS (dB)

20 OUTPUT POWER (dBm) 0 2 6 10 14 18 22 2 6 10 14 18 22 INPUT POWER (dBm) INPUT POWER (dBm)

AVAILABLE INPUT POWER OPTIONS DRIVE LEVEL INPUT DRIVE (dBm) J 3 – 8

TIPLIER PRODUCTS M 8 – 12 H 12 – 16

MUL V 16 – 20

COMMON APPLICATIONS

SATCOM PRODUCTS - COMMUNICATIONS RADIO ASTRONOMY APPLICATIONS RECEIVERS Interferometers and radiometers require broadband Microwave front ends usually employ a phase-locked frequency doublers for wideband receivers. source, such as a frequency synthesizer which has Frequency synthesizers are used to generate millime- extremely low phase-noise characteristics, especially for ter-wave frequencies to make the measurements. digital communications. The synthesizer uses a fundamental VCO which is locked to highly-stable crystal refer- MILLIMETER-WAVE SOURCES ence sources. The frequency limitation of many com- Millimeter-wave frequencies are used in research mercial VCOs and frequency dividers is 3500 MHz. A applications for atomic spectroscopy and for various multiplier is employed to extend the synthesizer range. communications and radars. A multiplier chain can be used to generate these frequencies from a lower RADAR RECEIVERS frequency source. Most radars employ frequency synthesizers which require frequency multipliers. The phase noise must FREQUENCY STANDARDS be low to avoid clutter noise. Highly-stable frequency sources can be multiplied to produce microwave sources used to measure the INSTRUMENTATION APPLICATIONS effect of the atmosphere or rocket exhaust on Frequency synthesizers which require multipliers are microwave signals. found in the front end of many measuring instruments which require low phase-noise LOs. One example is a spectrum analyzer.

381 MULTIPLIER PRODUCTS 382 CONVERSION HARMONIC OCTAVE BANDWIDTH SUBOCTAVE BANDWIDTH MULTIOCTAVE BANDWIDTH PASSIVE FREQUENCY DOUBLERS INPUT INPUT OUTPUT LOSS REJECTION MODEL FREQUENCYMODEL POWER FREQUENCY (dB) FUND./ODD OUTLINE NUMBER (GHz) (dBm) (GHz) (Typ./Max.) (dBc, Typ.) NUMBER PAGE MX2J004010MX2M004010*MX2H004010 0.02–0.5MX2V004010 0.02–0.5MX2J010060 0.02–0.5MX2M010060* 0.02–0.5MX2H010060 3–8MX2V010060 8–12 0.5–3 0.5–3 12–16SXS2J010060 0.5–3 16–20SXS2M010060* 0.5–3SXS2H010060 0.04–1 0.04–1 0.5–3 0.5–3 3–8 0.04–1SXS02J 8–12 0.5–3 0.04–1SXS01M* 12–16SXS03H 16–20MX2J030180-2C 10.5/13 10.5/13 3–8 10.5/13MX2M030180-2C* 8–12 0.5–3MX2H030180-2C 12–16 10.5/13 0.5–3 1.5–9 1–6 1–6 1.5–9MX2V030180-2C 1–6 0.5–3 1.5–9 1–6 1.5–9SXS2J040180SXS2M040180* -25 -25 1–6 1–6SXS2H040180 3–8 -25 10.5/15 10.5/15 8–12 3–8 1–6 8–12 10.5/15 -25 12–16 2–9 12–16SXS05J 10.5/15 2–9 16–20SXS04M* 2–9SXS06H MX2A MX2A MX2A 13/16 13/16 -15/20 -15/20MX2J060260 1–6 MX2A 1–6 13/16 -15/20 3–18 3–18MX2M060260* 3–8 1–6 -15/ 20 8–12 3–18MX2H060260 2–9 395 12–16 2–9 451 3–18MX2V060260 451 2–9* Detailed specification sheet inside catalog. MX2A MX2A 3–13 451 3–13 -20/25 -20/25 MX2A 12/15 13/16 12/15 13/16 -20/25 MX2A 3–13 12/15 13/16 3–13 4–18 4–18 3–8 12/15 8–12 4–18 396 451 12–16 3–8 160057 160057 451 8–12 451 160057 12–16 -15/20 -20/25 -15/20 -20/25 16–20 -15/20 -20/25 13/15 13/15 397 -15/20 459 13/15 4–18 4–18 459 4–18 6–26 6–26 161565 161565 MX2C MX2C 6–26 161565 MX2C 6–26 MX2C -20/25 -20/25 13/15 13/15 -20/25 398 460 13/15 399 452 12/18 12/18 460 452 12/18 452 160057 160057 12/18 160057 -20/25 -20/25 -20/25 -15/20 -15/20 400 459 -15/20 459 -15/20 161566 161566 161566 MX2D MX2D MX2D MX2D 401 460 460 402 452 452 452 MX2J020040MX2M020040*MX2H020040MX2V020040 1–2 1–2MX2J040080-2CMX2M040080-2C* 1–2MX2H040080-2C 1–2 2–4MX2V040080-2C 2–4 2–4MX2J080160-2C 3–8 8–12 2–4MX2M080160-2C* 12–16MX2H080160-2C 16–20 4–8MX2V080160-2C 4–8 3–8 8–12 4–8MX2J130260 12–16 4–8MX2M130260* 16–20 2–4 2–4MX2H130260 2–4MX2V130260 6.5–13 3–8 2–4 6.5–13 8–12MX2M180400 12–16 4–8 4–8MX2M200400 6.5–13 4–8 16–20 6.5–13 9.5/13 4–8 9.5/15 9.5/13 9–20 3–8 10–20 8–12 9.5/13 8–16 8–16 12–16 11/15 8–16 11/15 16–20 11/15 8–16 10 11/15 10 -20 -20 -20 MX2A 13–26 13–26 11/15 11/15 -20 13–26 11/15 -15/20 -15/20 13–26 11/15 -15/20 -15/20 MX2A 451 MX2A 18–40 11/13 11/15 20–40 MX2A 11/13 -15/20 -15/20 MX2C MX2C -15/20 11/13 MX2C -15/20 391 451 MX2C 12/14 451 12/14 392 MX2C 452 MX2C -15 -15 452 MX2C -15 452 MX2C -15 393 452 452 -15 MX2D MX2D -15 452 MX2D MX2D 394 452 452 MXF MXF 452 452 452 MX2M260400*MX2V260400MX2M180500 13–20 13–20 9–25 8–12 16–20 10 26–40 26–40 18–50 10/13 10/13 15/17 -15 -15 -15 MXF MXF MXF 390 452 452 383 MULTIPLIER PRODUCTS D00A*22 01 –01/0-52 233405 120373 -15/20 461 13/20 461 404 163124 163124 163124 4–40 459 459 403 -18/25 -18/25 -18/25 160057 10–13 160057 160057 13/18 -18/25 13/18 13/18 2–20 -18/25 -18/25 Custombandwidths/rejectionspecsavailable.PleasecontactMITEQ. NOTES: * Detailedspecificationsheetinsidecatalog. 6–26 TD0040LA2* 6–26 6–26 13/18 13/18 13/18 12–16 6–26 8–12 3–8 6–26 6–26 3–13 3–13 3–13 12–16 Custombandwidths/rejectionspecsavailable.PleasecontactMITEQ. NOTES: 8–12 3–8 * Detailedspecificationsheetinsidecatalog. SXS09H 3–13 SXS07M* 3–13 SXS08J 3–13 SXS2H060260 SXS2M060260* SXS2J060260 UBR(H)(B)(H)(y.Mx)(B,Tp)NME PAGE NUMBER (dBc,Typ.) (Typ./Max.) (GHz) (dBm) PAGE (GHz) NUMBER (dBc,Typ.) NUMBER (Typ./Max.) (GHz) (dBm) (GHz) NUMBER OE RQEC OE RQEC d)FN.ODOUTLINE FUND./ODD (dB) FREQUENCY POWER MODEL FREQUENCY OUTLINE FUND./ODD (dB) FREQUENCY POWER MODEL FREQUENCY For higher-orderpassivemultipliers,pleasecontactMITEQ. For higher-orderpassivemultipliers,pleasecontactMITEQ. NU NU UPTLS REJECTION LOSS OUTPUT INPUT INPUT REJECTION LOSS OUTPUT INPUT INPUT ASV RQEC DOUBLERS(CONT.) FREQUENCY PASSIVE UTOTV BANDWIDTH(CONT.) MULTIOCTAVE OVRINHARMONIC CONVERSION HARMONIC CONVERSION ACTIVE FREQUENCY DOUBLERS

HARMONIC INPUT INPUT OUTPUT OUTPUT CONVERSION REJECTION NOM. DC MODEL FREQUENCY POWER FREQUENCY POWER GAIN FUND./ODD POWER OUTLINE NUMBER (GHz) (dBm) (GHz) (dBm, Typ.) (dB, Typ.) (dBc, Typ.) (+15 V, mA) NUMBER NOTES PAGE SUBOCTAVE BANDWIDTH MAX2M180260 9–13 8–12 18–26 12–15 0–7 -20 175 MAX2K 1 455 MAX2P180260 9–13 -5–+5 18–26 12–15 10–20 -20 250 MAX2M 1 456 MAX2M180260-20P 9–13 8–12 18–26 18–22 10–14 -20 375 MAX2L 1, 4 456 MAX2P180260-20P 9–13 -5–+5 18–26 18–22 13–27 -20 450 MAX2N 1, 4 456

MAX2M260400* 13–20 8–12 26–40 12–15 0–7 -20 175 MAX2K 2 407 MAX2M260400W* 13–20 8–12 26–40 12–15 0–7 -20 175 MAX2G 2 408 MAX2M300500* 15–25 8–12 30–50 11–14 0–6 -20 175 MAX2K 3 409 MAX2M360500* 18–25 8–12 36–50 11–14 0–6 -20 175 MAX2K 3 410 MAX2M390440-20P* 19.5–22 8–12 39–44 18–22 10–14 -20 375 MAX2L 3, 4 411 MAX2M200380S 10–19 6–14 20–38 14–16 8–10 -20 200 MAX2M 456

OCTAVE BANDWIDTH

MAX2J020040 1–2 3–8 2–4 3–8 0 -20 +5/100 MAX2A2 453 MAX2M020040* 1–2 8–12 2–4 8–12 0 -20 +5/100 MAX2A2 412 MAX2H020040 1–2 12–16 2–4 12–16 0 -20 +5/100 MAX2A 453 MAX2V020040 1–2 16–20 2–4 16–20 0 -20 +5/100 MAX2A 453

MAX2J040080 2–4 3–8 4–8 3–8 0 -20 +5/100 MAX2A2 453 MAX2M040080* 2–4 8–12 4–8 8–12 0 -20 +5/100 MAX2A2 413 MAX2H040080 2–4 12–16 4–8 12–16 0 -20 +5/100 MAX2B 453

MAX2V040080 2–4 16–20 4–8 16–20 0 -20 +5/100 MAX2B 453 MUL

SYS2J060120* 3–6 5 6–12 12 7 -20 +5/120 157637 414 TIPLIER PRODUCTS SYS01J* 3–6 5 6–12 12 7 -20 +5/120 162011 415 SYS2H080160S 4–8 15 8–16 15 0 -20 150 157345 459

MAX2J080160 4–8 3–8 8–16 3–8 0 -20 125 MAX2B 453 MAX2M080160* 4–8 8–12 8–16 8–12 0 -20 125 MAX2B 416 MAX2H080160 4–8 12–16 8–16 12–16 0 -20 125 MAX2B 453 MAX2V080160 4–8 16–20 8–16 16–20 0 -20 125 MAX2B 453

SYS2J130260 6.5–13 3–8 13–26 3–8 0 -20 100 160833 460 SYS2M130260* 6.5–13 8–12 13–26 8–12 0 -20 100 160833 417 SYS2H130260 6.5–13 12–16 13–26 12–16 0 -20 100 160833 460 SYS2V130260 6.5–13 16–20 13–26 16–20 0 -20 350 160833 460

MAX2M180400 9–20 8–12 18–40 12–15 0–7 -20 175 MAX2K 455 MAX2P180400 9–20 -5–+5 18–40 12–15 7–20 -20 275 MAX2M 456 MAX2M200400* 10–20 8–12 20–40 12–15 0–7 -20 175 MAX2K 418 MAX2P200400 10–20 -5–+5 20–40 12–15 7–20 -20 175 MAX2M 456 MAX2M200400-20P* 10–20 8–12 20–40 18–22 6–14 -20 375 MAX2L 4 419 MAX2P200400-20P 10–20 -5–+5 20–40 18–22 13–27 -20 475 MAX2N 4 456 MAX2M250500 12.5–25 10 25–50 10 2 -18 150 MAX2K 455 MULTIOCTAVE BANDWIDTH

MAX2J010060 0.5–3 3–8 1–6 3–8 0 -20 +5/100 MAX2A2 453 MAX2M010060* 0.5–3 8–12 1–6 8–12 0 -20 +5/100 MAX2A2 420 MAX2H010060 0.5–3 12–16 1–6 12–16 0 -20 +5/100 MAX2A 453 MAX2V010060 0.5–3 16–20 1–6 16–20 0 -20 +5/100 MAX2A 453

MAX2J030180 1.5–9 3–8 3–18 3–8 0 -15/20 150 MAX2B 453 MAX2M030180* 1.5–9 8–12 3–18 8–12 0 -15/20 150 MAX2B 421 MAX2H030180 1.5–9 12–16 3–18 12–16 0 -15/20 150 MAX2B 453 MAX2V030180 1.5–9 16–20 3–18 16–20 0 -15/20 150 MAX2B 453

MAX2J060260 3–13 3–8 6–26 3–8 0 -12/15 210 MAX2C 454 MAX2M060260* 3–13 8–12 6–26 8–12 0 -12/15 210 MAX2C 422 MAX2H060260 3–13 12–16 6–26 12–16 0 -12/15 300 MAX2C 454 MAX2V060260 3–13 16–20 6–26 16–20 0 -12/15 350 MAX2C2 454

SYS2J150450* 7.5–22.5 3 15–45 +13 10 -20 220 163640 5 423

NOTES: (1) Available with WR42 on output. (2) Available with WR28 on output. (5) Requires negative bias -5 V at 50 mA. (3) Available with WR22/WR19 on output. (4) Requires negative bias -15 V at 70 mA. * Detailed specification sheet inside catalog.

384 385 MULTIPLIER PRODUCTS Y213*1. 2 5+8-040**1432 430 429 1 431 1 1 1 * * * 428 426 * 424 450 1 1 427 450 425 1 180 250 1 * 1 * -70 * -90 -70 * * 250 -50 250 250 +18 250 +20 250 +18 -80 +18 -16 -50 35 -70 -75 30 28 32–35 +15 +15 0 -20 +10 -20 +16 26–40 12 12 20–40 22.48–26.48 19–23 20–26.5 9–13 17.5 9–13 16–17.5 15 -5 14 SYS2X1735* -5 SYS2X1734* 10-12 SYS2X1530* 13–20 10–20 11.25–13.24 SYS2X1428* 10–13.25 SYS2X2640WG* 9.5–11.5 SYS2X1224* SYS2X2040* SYS2X1326* SYS2X1122* Y314*1 24 1 8 8 442 1 441 440 * 1 439 436 1 1 180 437 1 * 438 * 1 * 1 * 200 -80 200 * 200 * 180 -70 +12 320 -70 300 -60 -50 +16 42 -80 +16 -90 +15 435 +10 38–42 37–38 +23 12 434 36–37 +14.5 23–27 MXF 12 33.3–34.8 35.4–35.7 433 13 Theselectedbandwidth designsonthispagerepresentproductsthathavebuilt-infilteringfornarrowbandwidthapplications, 14 NOTES: 13 160212 N/A 3 12.6–14 15 12.5–12.9 13 +5/150 SYS3X1442* 12.2–12.5 157637 -55(filtered) SYS3X3842* SYS3X3738* 11.1–11.6 11.8–11.9 7.6–9 SYS3X3637* +5/150 18/22 SYS3X3550WG* -20 SYS3X3334* SYS3X2327* -20 32–40 +12 8–12 +12 4.2–7.2 10.66–13.33 +4 4.2–7.2 MX3M320400* +4 1.4–2.4 1.4–2.4 SYS02J* SYS3J042072* UBR(H)(B)(H)(B y.Mx)(B,y. +5,m)NME OEPAGE NOTE NUMBER (+15V, mA) (dBc,Typ.) (dB,Typ./Max.) (GHz) (dBm) (GHz) NUMBER NUMBER UBR(H)(B)(H)(B,Tp)(B,y. +5,m)NME OEPAGE NOTE NUMBER (+15V, mA) (dBc,Typ.) (dBm,Typ.) (GHz) (dBm) (GHz) NUMBER PAGE NOTE NUMBER (+15V, mA) (dBc,Typ.) (dBm,Typ.) (GHz) (dBm) (GHz) NUMBER OE RQEC OE RQEC OSSPRSINPWROUTLINE POWER SUPPRESSION LOSS FREQUENCY OUTLINE POWER POWER MODEL FREQUENCY SUPPRESSION POWER FREQUENCY POWER MODEL FREQUENCY OE RQEC OE RQEC OE UPESO OE OUTLINE POWER SUPPRESSION POWER FREQUENCY POWER MODEL FREQUENCY OUTLINE POWER SUPPRESSION POWER FREQUENCY POWER MODEL FREQUENCY *Foroutlines,seeindividualdatapages. ** Detailedspecificationsheetinsidecatalog. * 1 eursngtv is-5Vnmnl@2 Amaximum. (1) Requiresnegativebias-15Vnominal@20mA and militarymarkets. and representacrosssectionofthespecialtymultiplierproductsMITEQ hasmanufacturedforspecificsituationsinthecommercial EETBNWDHDOUBLERSANDTRIPLERS SELECT BANDWIDTH NU NU UPTCNESO AMNCNOM.DC HARMONIC CONVERSION OUTPUT NOM.DC INPUT HARMONIC INPUT OUTPUT OUTPUT INPUT INPUT NU NU UPTOTU AMNCNOM.DC HARMONIC OUTPUT OUTPUT INPUT INPUT NU NU UPTOTU AMNCNOM.DC HARMONIC OUTPUT OUTPUT INPUT INPUT Gz dm Gz dm y. dcTp)(1V A UBRNT PAGE NOTE NUMBER (+15V, mA) (dBc,Typ.) (dBm,Typ.) (GHz) (dBm) (GHz) ACTIVE DOUBLERSWITHPRINTEDFILTERS ACTIVE TRIPLERSWITHCARRIEROPTIONS ACTIVE TRIPLERSWITHPRINTEDFILTERS PASSIVE TRIPLERSABOVE 26GHz ACTIVE FREQUENCY TRIPLERS

MAX3J045050 1.5–1.67 3–8 4.5–5 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3M045050 1.5–1.67 8–12 4.5–5 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3H045050 1.5–1.67 12–16 4.5–5 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456

MAX3J050055 1.67–1.83 3–8 5–5.5 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3M050055 1.67–1.83 8–12 5–5.5 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3H050055 1.67–1.83 12–16 5–5.5 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456

MAX3J055060 1.83–2 3–8 5.5–6 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3M055060 1.83–2 8–12 5.5–6 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3H055060 1.83–2 12–16 5.5–6 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456

MAX3J060065 2–2.16 3–8 6–6.5 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3M060065 2–2.16 8–12 6–6.5 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3H060065 2–2.16 12–16 6–6.5 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456

MAX3J065070 2.16–2.33 3–8 6.5–7 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3M065070 2.16–2.33 8–12 6.5–7 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3H065070 2.16–2.33 12–16 6.5–7 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456

MAX3J070075 2.33–2.5 3–8 7–7.5 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456

MAX3M070075 2.33–2.5 8–12 7–7.5 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MUL MAX3H070075 2.33–2.5 12–16 7–7.5 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456 TIPLIER PRODUCTS MAX3J075080 2.5–2.66 3–8 7.5–8 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3M075080 2.5–2.66 8–12 7.5–8 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3H075080 2.5–2.66 12–16 7.5–8 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456

MAX3J080085 2.66–2.83 3–8 8–8.5 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3M080085 2.66–2.83 8–12 8–8.5 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3H080085 2.66–2.83 12–16 8–8.5 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456

MAX3J043052 1.43–1.73 3–8 4.3–5.2 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3M043052 1.43–1.73 8–12 4.3–5.2 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3H043052 1.43–1.73 12–16 4.3–5.2 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456

TRIPLERS – WIDE BANDWIDTHS

MAX3J047056 1.56–1.86 3–8 4.7–5.6 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3M047056 1.56–1.86 8–12 4.7–5.6 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3H047056 1.56–1.86 12–16 4.7–5.6 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456

MAX3J063074 2.1–2.46 3–8 6.3–7.4 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3M063074 2.1–2.46 8–12 6.3–7.4 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3H063074 2.1–2.46 12–16 6.3–7.4 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456

MAX3J070083 2.3–2.76 3–8 7–8.3 6–11 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3M070083 2.3–2.76 8–12 7–8.3 11–15 3 -60/-15 1 2:1/1.5:1 120 MAX3A 456 MAX3H070083 2.3–2.76 12–16 7–8.3 12–16 0 -60/-15 1 2:1/1.5:1 120 MAX3A 456

MAX3M154172 5.150–5.740 13 15.450–17.220 13 0 -60/-15 1 2:1/1.5:1 150* * * 456 MAX3M172190 5.740–6.330 13 17.220–18.990 13 0 -60/-15 1 2:1/1.5:1 150* * * 456

MAX3M300300 10 10–15 30 10 –13 0 -18 – 3:1/2:1 160* MAX2M 456 MAX3M260400 8.66–13.33 10 26–40 13 –16 3–6 -18 – 3:1/2:1 160 MAX2M 456 MAX3M300500 10–16.666 10 30–50 10 –13 0–3 -20 2 3:1/2:1 160 MAX2K 455

* Nominal current at +15 VDC. ** Consult MITEQ for specific packaging information. NOTE: MAX3 Series multipliers below 26 GHz have tunable comb filters. MITEQ can adjust these up and down to meet other frequency plans.

386 HIGHER ORDER ACTIVE MULTIPLIERS

HARMONIC INPUT INPUT OUTPUT OUTPUT CONVERSION REJECTION POWER VSWR NOM. DC MODEL FREQUENCY POWER FREQUENCY POWER GAIN IN/OUT FLATNESS IN/OUT POWER OUTLINE NUMBER (GHz) (dBm) (GHz) (dBm, Typ.) (dB, Typ.) (dBc, Min.) (±dB, Typ.) (Typ.) (+15 V, mA) NUMBER PAGE QUADRUPLERS MAX4J050055 1.25–1.375 3–8 5–5.5 6–11 3 -50/-15 1 2:1/1.5:1 150 MAX4A 457 MAX4M050055* 1.25–1.375 8–12 5–5.5 11–15 3 -50/-15 1 2:1/1.5:1 150 MAX4A 449 MAX4H050055 1.25–1.375 12–16 5–5.5 12–16 0 -50/-15 1 2:1/1.5:1 150 MAX4A 457

MAX4J055060 1.375–1.5 3–8 5.5–6 6–11 3 -50/-15 1 2:1/1.5:1 150 MAX4A 457 MAX4M055060 1.375–1.5 8–12 5.5–6 11–15 3 -50/-15 1 2:1/1.5:1 150 MAX4A 457 MAX4H055060 1.375–1.5 12–16 5.5–6 12–16 0 -50/-15 1 2:1/1.5:1 150 MAX4A 457

MAX4J060065 1.5–1.625 3–8 6–6.5 6–11 3 -50/-15 1 2:1/1.5:1 150 MAX4A 457 MAX4M060065 1.5–1.625 8–12 6–6.5 11–15 3 -50/-15 1 2:1/1.5:1 150 MAX4A 457 MAX4H060065 1.5–1.625 12–16 6–6.5 12–16 0 -50/-15 1 2:1/1.5:1 150 MAX4A 457

MAX4M062071* 1.55–1.78 8–12 6.2–7.1 11–15 3 -50/-15 2 2:1/1.5:1 150 MAX4A 449

MAX4J065070 1.625–1.75 3–8 6.5–7 6–11 3 -50/-15 1 2:1/1.5:1 150 MAX4A 457 MAX4M065070 1.625–1.75 8–12 6.5–7 11–15 3 -50/-15 1 2:1/1.5:1 150 MAX4A 457 MAX4H065070 1.625–1.75 12–16 6.5–7 12–16 0 -50/-15 1 2:1/1.5:1 150 MAX4A 457

MAX4J070075 1.75–1.875 3–8 7–7.5 6–11 3 -50/-15 1 2:1/1.5:1 150 MAX4A 457 MAX4M070075 1.75–1.875 8–12 7–7.5 11–15 3 -50/-15 1 2:1/1.5:1 150 MAX4A 457 MAX4H070075 1.75–1.875 12–16 7–7.5 12–16 0 -50/-15 1 2:1/1.5:1 150 MAX4A 457

MAX4V168176-23P 4.2–4.4 17 16.8–17.6 23 6 -60/-15 1.5 2:1/1.5:1 400 * * - MAX4M400480* 10–12 10–15 40–48 8–11 0 -18 2 3:1/2.5:1 150 MAX2H 449 MAX4M380460 9.5–11.5 8–12 38–46 10–13 2 -18 2 3:1/2.5:1 180 MAX2M 456 MAX4M360480 9–12 8–12 36–48 10–13 2 -18 2 3:1/2.5:1 180 MAX2M 456 MAX4M360500 9–12.5 8–12 36–50 10–13 2 -18 2 3:1/2.5:1 180 MAX2M 456

SYS4X1146* 10.25–11.5 12 41–46 12 0 -60 2 2.5:1/2.75:1 180 * * 443

* Detailed specification sheet inside catalog. ** Please contact MITEQ for specific packaging information. NOTE: MAX4 Series multipliers below 26 GHz have tunable comb filters. MITEQ can adjust these up and down to meet other frequency plans. TIPLIER PRODUCTS MUL

387 MULTIPLIER PRODUCTS 388 HARMONIC INPUT/ HARMONIC LOW COST DOUBLERS WITH PRINTED FILTERS LOW COST DOUBLERS HIGHER-ORDER ACTIVEHIGHER-ORDER (CONT.) MULTIPLIERS INPUT OUTPUT INPUT/OUTPUT CONVERSION VOLTAGE REJECTION POWER VSWR INPUT OUTPUT OUTPUT CONVERSION VOLTAGE REJECTION POWER VSWR COUPLED LOW COST DOUBLERS AND QUADRUPLERS WITH MONITOR PORTSLOW COST DOUBLERS AND QUADRUPLERS easily changed with slight filter modifications. In certain applications, there could be a need to monitor the output for an alarm, should the source fail. In certain applications, there could be a need to monitor the output for an alarm, should the source * Used to monitor main port. * taken with +12 dBm drive. Detailed specification sheet inside catalog. Data ** No negative voltage required for this product. ** No negative voltage required for this product. MODEL FREQUENCY FREQUENCY POWER GAIN CURRENT IN/OUTPWROUTLINE FLATNESS IN/OUT PORT NUMBER (GHz) (GHz) (dBm) (dBm, Typ.) (+5, -2.5,mA) (dB) (±dB, Typ.) (Typ.) RANGE (dB)* NUMBER PAGE MODEL FREQUENCYMODEL FREQUENCY POWER GAIN CURRENT IN/OUT FLATNESS IN/OUT OUTLINE NUMBER (GHz) (GHz) (dBm) (dB, Typ.) (+5, -2.5,mA) (dBc, Min.) (±dB, Typ.) (Typ.) NUMBER PAGE MAX2M045055-C 2.25–2.78MAX2M055059-C 2.75–2.94MAX4M104110-C 4.5–5.58MAX4M114126-C 5.51–5.59 2.6–2.75 2.86–3.14MAX4M127148-C 8–10 10.4–11 8–10 3.18–3.85 11.46–12.57MAX4M150162-C 12.72–14.84 3.75–4.05 8–10 8–10 8–10 0 0 15–16.17 0 8–10NOTES: coupler. These multipliers are designed with an additional 0 0 +5/120** +5/120** 0 -65/-15 -65/-15 120 120 120 1.5 1.5 -65/-15 120 -65/-15 -65/-15 2:1 2:1 1.5 -65/-15 1.5 -17 to -23 1.5 -17 to -23 2:1 MAX2E MAX2E 1.5 2:1 2:1 454 -17 to -23 454 2:1 -17 to -23 -17 to -23 MAX4D MAX4E MAX4D -17 to -23 457 458 457 MAX4E 458 MAX2M045055MAX2M055059 2.25–2.78MAX4M088095 2.75–2.94MAX4M109115MAX4M114120 2.2–2.37 4.5–5.58 2.73–2.88MAX4M114126 5.51–5.59 2.86–3.01MAX4M124133 8.88–9.48 10.91–11.53 2.86–3.14MAX4M127134* 8–10 11.46–12.03MAX4M127148 3.11–3.32 8–10 3.17–3.32 11.46–12.57MAX4M129138 8–10 8–10 12.46–13.28 3.18–3.85MAX4M139144 8–10 12.71–13.3 3.24–3.45MAX4M144146 8–10 0 12.72–14.84 3.48–3.61MAX4M145154 0 8–10 12.97–13.79 3.61–3.65MAX4M150162 0 8–10 0 13.95–14.46 3.62–4.22MAX4M152163 0 8–10 3.75–4.05MAX4M160169 +5/120** 14.4–14.66 0 8–10 +5/120** 14.5–15.4 0 8–10 3.8–4.08 -65/-15 0 120 8–10 -65/-15 15–16.17 120 15.21–16.31 4–4.22 0 120NOTES: 8–10 0The frequency plans can be multipliers are designed with printed filters, and for lower cost than tunable products. These 120 1.5 0 8–10 1.5 120 8–10 -65/-15 16–16.9 -65/-15 0 -65/-15 120 120 -65/-15 2:1 0 2:1 1.5 120 -65/-15 1.5 8–10 0 1.5 0 120 MAX2D -65/-15 MAX2D 1.5 -65/-15 120 2:1 1.5 454 -65/-15 2:1 454 2:1 120 1.5 -65/-15 0 MAX4B 2:1 1.5 MAX4B 120 120 -65/-15 MAX4B 2:1 1.5 457 MAX4B 2:1 1.5 457 -65/-15 457 MAX4B 2:1 -65/-15 1.5 457 -65/-15 2:1 120 MAX4B 457 MAX4C 2:1 1.5 MAX4B 450 1.5 2:1 1.5 457 MAX4C -65/-15 457 2:1 MAX4C 457 2:1 2:1 MAX4C 1.5 457 MAX4C MAX4C 457 2:1 457 457 MAX4C 457 389 MULTIPLIER PRODUCTS O01H4 0–5 –321 7X)NA15**447 * 445 115 * N/A 170 17(X2) -55 2–18 -10 7–13 2.85–3.15 500–150 10–13 EOM0218HW4* 142–158 SYS20M028032* Y5100*21 01 7 / .:/: 5 428444 149228 250 2.5:1/2:1 N/A -70 458 458 458 MAX5A MAX5A MAX5A 0 150 150 458 150 458 458 2:1/1.5:1 MAX5A 2:1/1.5:1 2:1/1.5:1 MAX5A MAX5A 10 458 1 150 458 1 458 1 150 150 MAX5A MAX5A 2:1/1.5:1 MAX5A 2:1/1.5:1 2:1/1.5:1 -60/-15 150 -60/-15 -60/-15 150 458 10 150 1 458 1 458 1 2:1/1.5:1 MAX5A 2:1/1.5:1 2:1/1.5:1 MAX5A MAX5A 0 3 -60/-15 1 3 150 -60/-15 1 -60/-15 1 150 458 150 10 458 458 2:1/1.5:1 MAX5A 2:1/1.5:1 2:1/1.5:1 MAX5A MAX5A 12–16 -60/-15 6–11 11–15 -60/-15 0 -60/-15 3 1 3 150 1 1 12.7–14.2 150 MAX5Seriesmultipliershavetunablecombfilters.MITEQcanadjusttheseupanddowntomeetotherfrequencyplans. 458 150 2 NOTE: 458 12.7–14.2 458 12.7–14.2 2:1/1.5:1 MAX5A 2:1/1.5:1 * Detailedspecificationsheetinsidecatalog. 2:1/1.5:1 MAX5A 0 12–16 MAX5A 12–16 3 -60/-15 6–11 3 8–12 11–15 -60/-15 -60/-15 3–8 1 SYS5J100100* 150 458 2.54–2.84 1 11.4–12.8 1 150 458 150 458 11.4–12.8 2.54–2.84 11.4–12.8 MAX5A 2:1/1.5:1 12–16 MAX5A 2:1/1.5:1 MAX5H127142 MAX5A 6–11 2.54–2.84 2:1/1.5:1 11–15 0 12–16 3 -60/-15 MAX5M127142 458 3 8–12 -60/-15 458 -60/-15 13.5–14.5 458 150 3–8 1 MAX5J127142 150 13.5–14.5 2.28–2.56 MAX5A 1 150 1 13.5–14.5 MAX5A MAX5A 2:1/1.5:1 2.28–2.56 2:1/1.5:1 12–16 12–16 2:1/1.5:1 MAX5H114127 6–11 2.28–2.56 8–12 11–15 0 150 3 3–8 -60/-15 150 MAX5M114127 458 3 150 -60/-15 1 458 -60/-15 12.5–13.5 458 2.7–2.9 1 2:1/1.5:1 MAX5J114127 1 12.5–13.5 MAX5A 2:1/1.5:1 2:1/1.5:1 12.5–13.5 MAX5A 2.7–2.9 MAX5A 12–16 2.7–2.9 12–16 MAX5H135145 6–11 8–12 11–15 1 -60/-15 0 150 1 1 -60/-15 3 3–8 150 MAX5M135145 -60/-15 3 150 11.5–12.5 2.5–2.7 2:1/1.5:1 MAX5J135145 11.5–12.5 2:1/1.5:1 11.5–12.5 2:1/1.5:1 2.5–2.7 -60/-15 12–16 2.5–2.7 12–16 -60/-15 -60/-15 MAX5H125135 0 6–11 8–12 11–15 1 3 3 1 1 3–8 MAX5M125135 10.5–11.5 2.3–2.5 MAX5J125135 10.5–11.5 10.5–11.5 0 2.3–2.5 12–16 3 -60/-15 3 12–16 6–11 2.3–2.5 -60/-15 11–15 -60/-15 MAX5H115125 8–12 3–8 MAX5M115125 9.5–10.5 9.5–10.5 2.1–2.3 MAX5J115125 12–16 9.5–10.5 6–11 11–15 0 2.1–2.3 3 3 12–16 2.1–2.3 MAX5H105115 8–12 9–9.5 3–8 MAX5M105115 9–9.5 9–9.5 1.9–2.1 MAX5J105115 12–16 6–11 11–15 1.9–2.1 12–16 1.9–2.1 MAX5H095105 8–12 3–8 MAX5M095105 8.5–9 8.5–9 1.8–1.9 MAX5J095105 8.5–9 1.8–1.9 12–16 1.8–1.9 MAX5H090095 8–12 3–8 MAX5M090095 1.7–1.8 MAX5J090095 1.7–1.8 1.7–1.8 MAX5H085090 MAX5M085090 MAX5J085090 *Foroutlines,seeindividualdatapages. ** UBR(H)(B)(H)(B,Tp)(B y. dc i. ±B y. Tp)(1 ,m)NME PAGE NUMBER (+15V,mA) (Typ.) (±dB,Typ.) (dBc,Min.) (dB, Typ.) (dBm,Typ.) (GHz) (dBm) (GHz) NUMBER Detailedspecificationsheetinsidecatalog. * OE RQEC OE RQEC OE ANI/U LTESI/U OE OUTLINE POWER IN/OUT FLATNESS IN/OUT GAIN POWER FREQUENCY POWER MODEL FREQUENCY UBR(H)(B)(H)(B y. dcTp)(1V A UBRPAGE NUMBER (+15V, mA) (dBc,Typ.) (dB,Typ.) (GHz) (dBm) (MHz) NUMBER OE RQEC OE RQEC OSSPESO OE OUTLINE POWER SUPRESSION LOSS FREQUENCY POWER MODEL FREQUENCY NU NU UPTOTU OVRINRJCINPWRVW NOM.DC VSWR POWER REJECTION CONVERSION OUTPUT OUTPUT INPUT INPUT NU NU UPTCNESO AMNCNOM.DC HARMONIC CONVERSION OUTPUT INPUT INPUT IHRODRATV MULTIPLIERS (CONT.) HIGHER ORDERACTIVE OTHER HIGHERORDERDESIGNS OTHER HIGHERORDERDESIGNS OBMULTIPLIER DESIGNS COMB QUINTUPLERS 33(X12) 24(X9) 18(X4) HARMONIC PASSIVE FREQUENCY DOUBLERS

MODEL: MX2M260400

ELECTRICAL SPECIFICATIONS Input frequency range 13 – 20 GHz Output frequency range 26 – 40 GHz Input power range 8 – 12 dBm nominal Conversion loss 10 dB typical 13 dB maximum Harmonic rejection Fundamental 15 dB typical Odd harmonic 15 dB typical

CONVERSION LOSS VS. FREQUENCY -5 -6 -7 -8 OUTLINE DRAWING -9 -10 MX2DMXF -11 -12 -13 .06 MUL -14 [1.52] .15 .131 MOUNTING [3.81] CONVERSION LOSS (dB) -15 INPUT [3.33] SURFACE 26 28 30 32 34 36 38 40 TIPLIER PRODUCTS RF OUTPUT FREQUENCY (GHz) OUTPUT .368 [9.35] .37 .613 [9.40] .85 [15.57] FUNDAMENTAL HARMONIC REJECTION [.21.59] VS. FREQUENCY -10

-15 .200 x2 .38 X2 Ø .079 [2.01] [5.08] [9.65] .43 MOUNTING HOLES [10.92] .31 -20 [7.87] -25 -30 NOTES: -35

REJECTION (dBc) 1. Optional SMA, K type male connectors in input, -40 K or V type male connectors in output. 13 14 15 16 17 18 19 20 INPUT FREQUENCY (GHz) 2. All dimensions shown in brackets [ ] are in millimeters.

OUTPUT POWER VS. INPUT POWER

(PIN = +10 dBm) 6

-2

-4

-6 OUTPUT POWER (dBm) -8

-10 5 7 9 11 13 15 INPUT POWER (dBm)

390 391 MULTIPLIER PRODUCTS

OUTPUT POWER (dBm) FUNDAMENTAL REJECTION (dB) CONVERSION LOSS (dB) -10 -12 -11 -10 Harmonic rejection 9.5dBtypical 8–12dBmnominal Optional inputpower 2–4GHzminimum Conversion loss 1–2GHzminimum Input powerrange Output frequencyrange Input frequencyrange 10 15 20 25 30 35 -8 -6 -4 -2 -9 -8 -7 0 2 4 6 d amnc20dBtypical 20dBtypical 16–20dBm 12–16dBm 3–8dBm Odd harmonic Fundamental MX2V020040 MX2H020040 MX2J020040 2 5 2 UDMNA EETO VS.FREQUENCY REJECTION FUNDAMENTAL OVRINLS VS.FREQUENCY LOSS CONVERSION ELECTRICAL SPECIFICATIONS UPTPWRV.IPTPOWER INPUT VS. POWER OUTPUT . . . . 4 3.6 3.2 2.8 2.4 . . . . 4 3.6 3.2 2.8 2.4 11 15 13 11 9 7 INPUT POWER (dBm) FREQUENCY (GHz) FREQUENCY (GHz) (P IN = +10dBm) ASV RQEC DOUBLERS(CONT.) FREQUENCY PASSIVE 13 dBmaximum MODEL: MX2M020040 NOTE: .075 [1.91] .Alldimensionsshowninbrackets[]aremillimeters. 1. .075 [1.91] .80 [20.32] .88 [22.35] HOLES) (2 MOUNTING DIA. THRU .101 [2.56] ULN DRAWING OUTLINE 1.25 [31.75] 1.10 [27.94] MX2D MX2A .38 [9.65]TYP. RF INPUT (TYP. 2PLACES) FEMALE REPLACEABLE SMA FIELD RF OUTPUT .17 [4.32] [12.19] .48 .17 [4.32] .28 [7.11] .95 [24.13] MULTIPLIER PRODUCTS 392 .38 [9.65] TYP. 2 PLACES TYP. [9.65] .75 SQ. [19.05] OUTPUT .28 [7.11] .38 .235 [5.97] B A B A DIM A DIM B INPUT A MX2C MX2D B) OUTLINE DRAWING A) PLACES B SMA FIELD REPLACEABLE FEMALE (.012 [.30] DIA. PIN ON HOUSING) (TYP. 2 PLACES) -1 .226 [5.74] .121 [3.07] .64 [16.26] (2 MARKED OUTLINE DASH NO. PLACES .089 [2.26] DIA. 1. All dimensions shown in brackets [ ] are in millimeters. .055 [1.40] 2-56 THRU (2 MARKED THRU, NOTE: MODEL: MX2M040080-2C MODEL: 13 dB maximum PASSIVE FREQUENCY (CONT.) DOUBLERS = +10 dBm) IN (P FREQUENCY (GHz) FREQUENCY (GHz) INPUT POWER (dBm) 7 9 11 13 15 4.8 5.6 6.4 7.2 8 4.8 5.6 6.4 7.2 8 OUTPUT POWER VS. INPUT POWER ELECTRICAL SPECIFICATIONS ELECTRICAL CONVERSION LOSS VS. FREQUENCY FUNDAMENTAL REJECTION VS. FREQUENCY 4 4 5 FundamentalOdd harmonic 20 dB typical 20 dB typical MX2J040080-2CMX2H040080-2CMX2V040080-2C 3–8 dBm 12–16 dBm 16–20 dBm 0 6 4 2

-9 -4 -6 -8 -2 15 10 35 30 25 20

Harmonic rejection Input frequency rangeOutput frequency rangeInput power range 2 – 4 GHz minimum Conversion loss minimum 4 – 8 GHz Optional input power nominal 8 – 12 dBm dB typical 11

-10 -13 -14 -11 -12

-10

FUNDAMENTAL REJECTION (dB) REJECTION FUNDAMENTAL CONVERSION LOSS (dB) LOSS CONVERSION OUTPUT POWER (dBm) POWER OUTPUT 393 MULTIPLIER PRODUCTS

OUTPUT POWER (dBm) FUNDAMENTAL REJECTION (dB) CONVERSION LOSS (dB) -10 -14 -13 -12 -11 -10 Harmonic rejection 11dBtypical 8–12dBmnominal Optional inputpower 8–16GHzminimum Conversion loss 4–8GHzminimum Input powerrange Output frequencyrange Input frequencyrange 10 15 20 25 30 35 -8 -6 -4 -2 -9 0 2 4 6 d amnc20dBtypical 20dBtypical 16–20dBm Odd harmonic 12–16dBm 3–8dBm Fundamental MX2V080160-2C MX2H080160-2C MX2J080160-2C 11 15 13 11 9 7 5 . 121. 4416 14.4 12.8 11.2 9.6 8 . 121. 4416 14.4 12.8 11.2 9.6 8 UDMNA EETO VS.FREQUENCY REJECTION FUNDAMENTAL OVRINLS VS.FREQUENCY LOSS CONVERSION ELECTRICAL SPECIFICATIONS UPTPWRV.IPTPOWER INPUT VS. POWER OUTPUT INPUT POWER (dBm) FREQUENCY (GHz) FREQUENCY (GHz) (P IN = +10dBm) ASV RQEC DOUBLERS(CONT.) FREQUENCY PASSIVE 13 dBmaximum MODEL: MX2M080160-2C NOTE: THRU, MARKED (2 2-56 THRU .055 [1.40] .089 [2.26]DIA. .Alldimensionsshowninbrackets[]aremillimeters. 1. PLACES AHNO. DASH OUTLINE MARKED (2 .64 [16.26] 1.2 57].121[3.07] .226[5.74] -1 (TYP. 2PLACES) (.012 [.30]DIA.PINONHOUSING) SMA FIELDREPLACEABLEFEMALE B PLACES A) ULN DRAWING OUTLINE B) A MX2D MX2C INPUT I DIMB A DIM A B A B .235 [5.97] .38 .28 [7.11] OUTPUT .75 SQ.[19.05] TYP. [9.65] TYP. 2PLACES .38 [9.65] MULTIPLIER PRODUCTS 394 .698 [17.73] .075 [1.91] .175 [4.45] .57 [14.48] .29 [7.37] .18 [4.57] .35 [8.89] SMA FEMALE (TYP. BOTH ENDS) .18 [4.57] .48 [12.19] RF OUTPUT .015 [.38] DIA. PIN (TYP. BOTH ENDS) MX2D .43 [10.92] .38 [9.65] OUTLINE DRAWING 0-80 HARDWARE THRU .070 [1.78] DIA. HOLES removing the SMAhardware connectors and mounting as shown. 1. by Doubler may be readily used as is, or as a drop-in 2. All dimensions shown in brackets [ ] are in millimeters. .158 [4.0] RF INPUT .273 [6.93] .007 [.178] .428 [10.87] .585 [14.85] .16 [4.06] .273 [6.93] .36 [9.14] NOTES: .59 [15.0] .11 [2.79] MODEL: MX2M130260 MODEL: 13 dB maximum PASSIVE FREQUENCY (CONT.) DOUBLERS = +10 dBm) IN (P FREQUENCY (GHz) FREQUENCY (GHz) INPUT POWER (dBm) 7 9 11 13 15 15.6 18.2 20.8 23.4 26 15.6 18.2 20.8 23.4 26 OUTPUT POWER VS. INPUT POWER ELECTRICAL SPECIFICATIONS ELECTRICAL CONVERSION LOSS VS. FREQUENCY FUNDAMENTAL REJECTION VS. FREQUENCY 5 13 13 FundamentalOdd harmonic 15 dB typical 15 dB typical MX2J130260MX2H130260MX2V130260 3–8 dBm 12–16 dBm 16–20 dBm 0 6 4 2

-7 -8 -9 -4 -6 -8 -2 15 10 35 30 25 20

Harmonic rejection Input frequency rangeOutput frequency rangeInput power range 6.5 – 13 GHz minimum Conversion lossGHz minimum 13 – 26 Optional input power nominal 8 – 12 dBm dB typical 11

-10 -11 -12 -10

CONVERSION LOSS (dB) LOSS CONVERSION FUNDAMENTAL REJECTION (dB) REJECTION FUNDAMENTAL OUTPUT POWER (dBm) POWER OUTPUT 395 MULTIPLIER PRODUCTS

OUTPUT POWER (dBm) FUNDAMENTAL REJECTION (dB) CONVERSION LOSS (dB) -10 -14 -13 -12 -11 -10 Harmonic rejection 10.5dBtypical 8–12dBmnominal Optional inputpower 0.04–1GHzminimum Conversion loss 0.02–0.5GHzminimum Input powerrange Output frequencyrange Input frequencyrange 10 15 20 25 30 35 -8 -6 -4 -2 -9 0 2 4 6 d amnc25dBtypical 25dBtypical 16–20dBm 12–16dBm 3–8dBm Odd harmonic Fundamental MX2V004010 MX2H004010 MX2J004010 .04 .04 5 UDMNA EETO VS.FREQUENCY REJECTION FUNDAMENTAL ELECTRICAL SPECIFICATIONS UPTPWRV.IPTPOWER INPUT VS. POWER OUTPUT OVRINLS VS.FREQUENCY LOSS CONVERSION 22.2 66.0 1 .808 .616 .424 .232 22.2 66.0 1 .808 .616 .424 .232 11 15 13 11 9 7 INPUT POWER (dBm) FREQUENCY (GHz) FREQUENCY (GHz) (P IN = +10dBm) ASV RQEC DOUBLERS(CONT.) FREQUENCY PASSIVE 13 dBmaximum MODEL: MX2M004010 NOTE: .075 [1.91] .Alldimensionsshowninbrackets[]aremillimeters. 1. .075 [1.91] .80 [20.32] .88 [22.35] HOLES) (2 MOUNTING DIA. THRU .101 [2.56] ULN DRAWING OUTLINE 1.25 [31.75] 1.10 [27.94] MX2D .38 [9.65]TYP. MX2A RF INPUT (TYP. 2PLACES) FEMALE REPLACEABLE SMA FIELD RF OUTPUT .17 [4.32] [12.19] .48 .17 [4.32] .28 [7.11] .95 [24.13] MULTIPLIER PRODUCTS 396 .95 [24.13] .28 [7.11] .17 [4.32] .48 [12.19] .17 [4.32] RF OUTPUT SMA FIELD REPLACEABLE FEMALE (TYP. 2 PLACES) RF INPUT MX2D MX2A .38 [9.65] TYP. 1.10 [27.94] 1.25 [31.75] OUTLINE DRAWING .101 [2.56] DIA. THRU (2 MOUNTING HOLES) .88 [22.35] .80 [20.32] 1. All dimensions shown in brackets [ ] are in millimeters. .075 [1.91] .075 [1.91] NOTE: MODEL: MX2M010060 MODEL: 15 dB maximum PASSIVE FREQUENCY (CONT.) DOUBLERS = +10 dBm) IN (P FREQUENCY (GHz) FREQUENCY (GHz) INPUT POWER (dBm) 23456 OUTPUT POWER VS. INPUT POWER ELECTRICAL SPECIFICATIONS ELECTRICAL CONVERSION LOSS VS. FREQUENCY FUNDAMENTAL REJECTION VS. FREQUENCY 123456 5 7 9 11 13 15 1 FundamentalOdd harmonic 15 dB typical 20 dB typical MX2J010060MX2H010060MX2V010060 3–8 dBm 12–16 dBm 16–20 dBm 0 6 4 2 -9

-4 -6 -8 -2

15 10 35 30 25 20

Harmonic rejection Input frequency rangeOutput frequency rangeInput power range 0.5 – 3 GHz minimum Conversion loss minimum 1 – 6 GHz Optional input power nominal 8 – 12 dBm dB typical 10.5 -10 -13 -14 -11 -12

-10

CONVERSION LOSS (dB) LOSS CONVERSION OUTPUT POWER (dBm) POWER OUTPUT FUNDAMENTAL REJECTION (dB) REJECTION FUNDAMENTAL 397 MULTIPLIER PRODUCTS

CONVERSION LOSS (dB) AND FUNDAMENTAL REJECTION (dB) 13dBtypical Harmonic rejection 8–12dBmnominal Optional inputpower 1–6GHzminimum Conversion loss 0.5–3GHzminimum Input powerrange Output frequencyrange Input frequencyrange -45 -40 -35 -30 -25 -20 -15 -10 UDMNA EETO VS.FREQUENCY REJECTION FUNDAMENTAL d amnc-25dBtypical -20dBtypical 12–16dBm 3–8dBm Odd harmonic Fundamental SXS2H010060 SXS2J010060 -5 0020 0040 006000 5000 4000 3000 2000 1000 ELECTRICAL SPECIFICATIONS CONVERSION LOSS(dB) OVRINLOSSAND CONVERSION FUNDAMENTAL REJECTION(dB) FREQUENCY (MHz) ASV RQEC DOUBLERS(CONT.) FREQUENCY PASSIVE 16 dBmaximum MODEL: SXS2M010060 NOTE: 0.410 [10.414] 0.590 [14.986] 2X 0.375 [9.525] .Alldimensionsshowninbrackets[]aremillimeters. 1. 0.282 [7.163] 0.236 [5.994] ULN DRAWING OUTLINE FEMALE CONNECTORFEMALE REPLACEABLE 2X TYPE [20.32] 0.800 160057 SMAFIELD MX2D MOUNTING HOLES 4X Ø0.080[0.203]DIA. THRU 0.480 [12.192] 0.055 [1.397] 0.295 [7.493] 0.200 [5.08] PASSIVE FREQUENCY DOUBLER (CONT.)

MODEL: SXS01M

ELECTRICAL SPECIFICATIONS Input frequency range 0.5 – 3 GHz minimum Output frequency range 1 – 6 GHz minimum Input power range 8 – 12 dBm nominal Conversion loss 13 dB typical 16 dB maximum Optional input power SXS02J 3–8 dBm SXS03H 12–16 dBm Harmonic rejection Fundamental -20 dB typical Odd harmonic -25 dB typical

CONVERSION LOSS AND FUNDAMENTAL REJECTION VS. FREQUENCY OUTLINE DRAWING -5 161565MX2D

-10 MUL

-15 CONVERSION LOSS (dB) .60 [15.24] TIPLIER PRODUCTS .500 [12.70] -20 .30 [7.62] 4X Ø.070 -25 .050 [Ø1.778] [1.27] .050 [1.27] MOUNTING HOLES -30

-35 .16 [4.06] F 2F FUNDAMENTAL REJECTION (dB) .220 [5.588] -40 .32 [8.13] CONVERSION LOSS (dB) AND

FUNDAMENTAL REJECTION (dB) -45 1000 2000 3000 4000 5000 6000 FREQUENCY (MHz)

CIRCUIT BOARD .04 [1.02]

MOUNTING SURFACE

NOTE: 1. All dimensions shown in brackets [ ] are in millimeters.

398 PASSIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MX2M030180-2C

ELECTRICAL SPECIFICATIONS Input frequency range 1.5 – 9 GHz minimum Output frequency range 3 – 18 GHz minimum Input power range 8 – 12 dBm nominal (performance guaranteed at +10 dBm) Conversion loss 12 dB typical 15 dB maximum Optional input power M/N MX2J030180-2C 3–8 dBm (performance guaranteed at 5.5 dBm) M/N MX2H030180-2C 12–16 dBm (performance guaranteed at 14 dBm) M/N MX2V030180-2C 16–20 dBm (performance guaranteed at 18 dBm) Harmonic rejection Fundamental 15 dB typical Odd harmonic 20 dB typical

CONVERSION LOSS VS. FREQUENCY ) OUTLINE DRAWING

B -9 d (

S -10 MX2D S MX2C O S L -11 T N C

O SMA FIELD REPLACEABLE FEMALE I

U -12

S (.012 [.30] DIA. PIN ON HOUSING) D R (TYP. 2 PLACES) E O -13 V R

N INPUT P O -14 B C

R 3 6 9 12 15 18 E I FREQUENCY (GHz) L

P A .38 [9.65] I ) T B FUNDAMENTAL REJECTION VS. FREQUENCY TYP. 2 PLACES d L ( 2-56 THRU U

N 35 (2 PLACES O

M .75 SQ. [19.05] I

T 30 MARKED A) C E

J .055 [1.40]

E 25 R

L 20 .38 TYP. [9.65] A T

N A B

E 15

M .64 [16.26] A 10

D B A

N 3 6 9 12 15 18 U

F FREQUENCY (GHz) OUTPUT

.089 [2.26] DIA. OUTPUT POWER VS. INPUT POWER .235 [5.97] THRU, (2 PLACES (PIN = +10 dBm) MARKED B) 6 .28 [7.11]

) OUTLINE m 2 DIM A DIM B B DASH NO. d ( 0 R -1 .226 [5.74] .121 [3.07] E

W -2 O P

T -4 U Notes: P T -6 1. Dimensions are in inches [millimeters] U

O Tolerance as follows: -8 .xx = ±0.01 [.xx = ±0.25] 1 1 /

.xxx = ±0.005 [.xxx = ±0.13] 7 -10 2 /

5 7 9 11 13 15 7 0 : d

INPUT POWER (dBm) e s i v e R 399

PASSIVE FREQUENCY DOUBLER (CONT.)

MODEL: SXS2M040180

ELECTRICAL SPECIFICATIONS Input frequency range 2 – 9 GHz minimum Output frequency range 4 – 18 GHz minimum Input power range 8 – 12 dBm nominal Conversion loss 13 dB typical 15 dB maximum Optional input power SXS2J040180 3–8 dBm SXS2H040180 12–16 dBm Harmonic rejection Fundamental -20 dB typical Odd harmonic -25 dB typical

CONVERSION LOSS AND FUNDAMENTAL REJECTION VS. FREQUENCY OUTLINE DRAWING -0 160057MX2D ) D dB -5 N

A CONVERSION LOSS (dB) N ( MUL ) -10 IO 0.236 [5.994] T dB 0.282 [7.163] 0.055 [1.397] ( TIPLIER PRODUCTS

EC -15 J LOSS RE -20 0.590 [14.986] 0.480 [12.192] L N

TA -25 SIO

EN 2X 0.375 0.800 ER M -30 4X Ø0.080 [0.203] DIA. THRU V [9.525] [20.32] MOUNTING HOLES N DA

O -35 C

FUN FUNDAMENTAL REJECTION (dB) 0.295 [7.493] -40 4000 6000 8000 10000 12000 14000 16000 18000 FREQUENCY (MHz) 0.410 [10.414] 0.200 [5.08] 2X TYPE SMA FIELD REPLACEABLE FEMALE CONNECTOR

NOTE: 1. All dimensions shown in brackets [ ] are in millimeters.

400 401 MULTIPLIER PRODUCTS

CONVERSION LOSS (dB) AND

FUNDAMENTAL REJECTION (dB) 13dBtypical Harmonic rejection 8–12dBmnominal Optional inputpower 4–18GHzminimum Conversion loss 2–9GHzminimum Input powerrange Output frequencyrange Input frequencyrange -40 -35 -30 -25 -20 -15 -10 UDMNA EETO VS.FREQUENCY REJECTION FUNDAMENTAL -5 -0 d amnc-25dBtypical -20dBtypical 12–16dBm 3–8dBm Odd harmonic Fundamental SXS06H SXS05J 0060 0010010010016000 14000 12000 10000 8000 6000 4000 ELECTRICAL SPECIFICATIONS FUNDAMENTAL REJECTIONFUNDAMENTAL (dB) UPTPWRV.IPTPOWER INPUT VS. POWER OUTPUT OVRINLOSSAND CONVERSION (P FREQUENCY (MHz) CONVERSION LOSS(dB) IN = +10dBm) ASV RQEC DOUBLERS(CONT.) FREQUENCY PASSIVE 15 dBmaximum MODEL: SXS04M 18000 NOTE: .Alldimensionsshowninbrackets[]aremillimeters. 1. ULN DRAWING OUTLINE 161566 MX2D PASSIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MX2M060260

ELECTRICAL SPECIFICATIONS Input frequency range 3 – 13 GHz minimum Output frequency range 6 – 26 GHz minimum Input power range 8 – 12 dBm nominal Conversion loss 12 dB typical 18 dB maximum Optional input power MX2J060260 3–8 dBm MX2H060260 12–16 dBm MX2V060260 16–20 dBm Harmonic rejection Fundamental 15 dB typical Odd harmonic 20 dB typical

CONVERSION LOSS VS. FREQUENCY -9 OUTLINE DRAWING

-10 MX2D -11 .43 [10.92] .29 [7.37] MUL -12 .16 [4.06] .38 .18 [4.57] -13 .11 [2.79] [9.65] TIPLIER PRODUCTS

-14 .35 [8.89] CONVERSION LOSS (dB) 6 10 14 18 22 26 .59 [15.0] .698 [17.73] FREQUENCY (GHz)

FUNDAMENTAL REJECTION VS. FREQUENCY .273 [6.93] SMA FEMALE 35 0-80 HARDWARE THRU (TYP. BOTH ENDS) .070 [1.78] DIA. HOLES 30

25 .428 [10.87] .158 [4.0] .18 [4.57] 20 .075 [1.91] 15 .36 [9.14] 10 .48 [12.19] .57 [14.48] 6 10 14 18 22 26 RF FUNDAMENTAL REJECTION (dB) FREQUENCY (GHz) INPUT .007 [.178] RF OUTPUT .175 [4.45] .015 [.38] DIA. PIN OUTPUT POWER VS. INPUT POWER .273 [6.93] (TYP. BOTH ENDS) .585 [14.85] (PIN = +10 dBm) 6

2 NOTES: 0 1. Doubler may be readily used as is, or as a drop-in by removing the SMA connectors and mounting hardware -2 as shown.

-4 2. All dimensions shown in brackets [ ] are in millimeters. -6 OUTPUT POWER (dBm) -8

-10 5 7 9 11 13 15 INPUT POWER (dBm)

402

403 MULTIPLIER PRODUCTS

CONVERSION LOSS (dB) AND

FUNDAMENTAL REJECTION (dB) 13dBtypical Harmonic rejection 8–12dBmnominal Optional inputpower 6–26GHzminimum Conversion loss 3–13GHzminimum Input powerrange Output frequencyrange Input frequencyrange -40 -35 -30 -25 -20 -15 -10 d amnc-25dBtypical -18dBtypical 12–16dBm 3–8dBm Odd harmonic Fundamental SXS2H060260 SXS2J060260 -5 -0 UDMNA EETO VS.FREQUENCY REJECTION FUNDAMENTAL 0090 20 50 80 10 24000 21000 18000 15000 12000 9000 6000 ELECTRICAL SPECIFICATIONS FUNDAMENTAL REJECTIONFUNDAMENTAL (dB) OVRINLOSSAND CONVERSION FREQUENCY (MHz) CONVERSION LOSS(dB) ASV RQEC DOUBLERS(CONT.) FREQUENCY PASSIVE 17 dBmaximum MODEL: SXS2M060260 27000 0.410 [10.414] NOTE: 0.590 [14.986] 2X 0.375 [9.525] 0.282 [7.163] 0.236 [5.994] .Alldimensionsshowninbrackets[]aremillimeters. 1. ULN DRAWING OUTLINE FEMALE CONNECTORFEMALE REPLACEABLE 2X TYPE [20.32] 0.800 160057 SMAFIELD MOUNTING HOLES 4X Ø0.080[0.203]DIA. THRU 0.480 [12.192] 0.055 [1.397] 0.295 [7.493] 0.200 [5.08] MULTIPLIER PRODUCTS 404 4] Ø.070 [178] THRU Ø.070 [178] MTG. HOLE 4 PLACES OUT 0.045 [0.11 0.16 [0.406] CIRCUITRY 2F X2 MX2D 163124 0.050 [0.127] 0.60 [1.52] 0.500 [1.27] F OUTLINE DRAWING 0.220 [0.559] IN SURFACE MOUNTING FUNCTIONAL BLOCK DIAGRAM FUNCTIONAL BLOCK 1. All dimensions shown in brackets [ ] are in millimeters. 0.32 CIRCUIT BOARD CIRCUIT 0.050 [0.127] [0.813] NOTE: 27000 MODEL: SXS07M MODEL: 18 dB maximum PASSIVE FREQUENCY (CONT.) DOUBLERS CONVERSION LOSS (dB) FREQUENCY (MHz) CONVERSION LOSS AND FUNDAMENTAL (dB) REJECTION ELECTRICAL SPECIFICATIONS ELECTRICAL 6000 9000 12000 15000 18000 21000 24000 FundamentalOdd harmonic -18 dB typical -25 dB typical SXS08JSXS09H 3–8 dBm dBm 12–16 FUNDAMENTAL REJECTION VS. FREQUENCY

-0 -5

-35 -40 -10 -15 -20 -25 -30

) dB ( N TIO EC J RE TAL MEN DA Harmonic rejection FUN Input frequency rangeOutput frequency rangeInput power range 3 – 13 GHz minimum Conversion loss minimum 6 – 26 GHz Optional input power nominal 8 – 12 dBm dB typical 13

LOSS N SIO ER V N O C D N A ) dB ( 405 MULTIPLIER PRODUCTS lizing MITEQ’s low-noiseamplifiers. diodes willyield+5dBmoutputwith+20input. An activeversionisalsoavailablewitha+10dBmoutpututi- minimuminputpowerof+10 dBm isrequiredtoachieve-3outputusinglow-leveldiodes.Higherlevel A This triple-balancedpassivefrequencymultiplierisusefulasasignalsourceinmillimeterreceiversortransmitters. Outputphasenoiseequivalentto • IsolationF • 13dBtypical ...... Conversionloss • 4to40GHz ...... RFoutput • 2to20GHz RFinput...... • FEATURES passive Schottkydiodemixer UPTPRMTR ODTO NT I.TP MAX. TYP. MIN. UNITS CONDITION MAX. TYP. MAX. TYP. MIN. MIN. UNITS UNITS OUTPUT PARAMETERS CONDITION CONDITION TRANSFER CHARACTERISTICS INPUT PARAMETERS slto Fi oR u o4 H B2 25 18 20 15 dB 4to40GHz dB 4to40GHz RFintoout Isolation Conversion loss(RF=+10dBm) FfeunyrneGz440 12 -3 4 dBm GHz dBm Input=+10 +13 3:1 20 Input=+10 +10 +7 Ratio 2 dBm GHz Active option L Power diode IF frequencyrange RF powerrange RF VSWR RF frequencyrange 4 TO40GHzOUTPUTLOW-NOISEFREQUENCYDOUBLER in nu 2 B 5 dBm Input=+20 H /F out ...... 30dBtypical ...... ELECTRICAL SPECIFICATIONS MODEL: 8t 6Gzd 113 33 15 30 11 27 13 25 dB dB dB 18 to26GHz dB 12 to32GHz 18 to26GHz 12 to32GHz TD0040LA2 MULTIPLIER PRODUCTS 406 (RF IN = +10 dBm) (RF IN = +10 INPUT FREQUENCY (GHz) ISOLATION (INPUT TO OUTPUT) ISOLATION LE CONNECTOR (TYP. 2 PLACES) .068 [1.727] TYPE K FIELD REPLACEABLE FEMA .590 [14.99] 2 6 10 14 18 22

10 20 30 40 50 ISOLATION (dB) ISOLATION GENERAL NOTES 1. available. Input or output LNAs 2. is hermetically sealed. Existing package 3. input. Burn out = +23 dBm IN OPTIONAL SPACER PLATE .098 [2.489] DIA. THRU MOUNTING HOLES (TYP. 4 PLACES) 1.5 [38.10] OUT 13 dBm OUTLINE DRAWING .625 [15.875] .875 [22.225] [5.33] .660 [16.76] .210 TD0040LA2 TYPICALTD0040LA2 DATA TEST .110 [2.79] VSWR 7 dBm CONVERSION LOSS [5.59] .330 [8.38] INPUT FREQUENCY (GHz) .220 OUTPUT FREQUENCY (GHz) 10 dBm (RF IN = 2 TO 22 GHz, INPUT = +7, +10, +13 dBm) 4 12 20 28 36 44 2 6 10 14 18 22

0 4 8

12 16 20 6:1 5:1 4:1 3:1 2:1 1:1

CONVERSION LOSS (dB) LOSS CONVERSION VSWR (RATIO) VSWR NOTE: Test data supplied at 25°C; Conversion loss, LO-RF isolation. data supplied at 25°C; Conversion Test NOTE: MAXIMUM RATINGS Specification temperature...... +25°C Operating temperature ...... -54 to +85°C Storage temperature ...... -65 to +125°C NOTE: All dimensions shown in brackets [ ] are in millimeters. NOTE:

ACTIVE FREQUENCY DOUBLERS

MODEL: MAX2M260400

ELECTRICAL SPECIFICATIONS Input frequency range 13 – 20 GHz Output frequency range 26 – 40 GHz Input power range 10 – 15 dBm nominal Harmonic rejection Fundamental 18 dB typical Odd harmonic 18 dB typical

OUTPUT POWER VS. FREQUENCY

) 20 19

dBm 18 OUTLINE DRAWING 17

ER ( 16 3

W MAX2K 15 3 3 33 14 3 13 3 3 .15 .131 12 +VDC 11 [3.81] [3.33] OUTPUT PO 10 .06 MOUNTING 26 28 30 32 34 36 38 40 [1.52] SURFACE INPUT OUTPUT FREQUENCY (GHz) .363 OUTPUT [9.35] .613 FUNDAMENTAL REJECTION VS. FREQUENCY .85 [15.57] TIPLIER PRODUCTS [21.59] (PIN = +10 dBm)

MUL -20

) -25

c X1 X3 -30

dB .200 [5.08] -35 X2 .38 .43 X2 Ø.079 [2.01] 3 [9.65] MOUNTING HOLES ON ( 3 [10.92] I .31 -40 3 33 3 [7.87] -45 3 ECT

J -50 3 RE -55 NOTES: -60 1. Optional input connectors SMA, K or output connectors 13 14 15 16 17 18 19 20 K or V type male. INPUT FREQUENCY (GHz) 2. Optional waveguide output available, please contact MITEQ.

3. All dimensions shown in brackets [ ] are in millimeters.

407 ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MAX2M260400W (WAVEGUIDE WR28 OUTPUT)

ELECTRICAL SPECIFICATIONS Input frequency range 13 – 20 GHz Output frequency range 26 – 40 GHz Input power range 8 – 12 dBm Harmonic rejection Fundamental > 20 dBc typical Odd harmonic > 20 dBc typical

OUTPUT POWER VS. FREQUENCY 17

13 OUTLINE DRAWING 11

9 MAX2G

OUTPUT POWER (dBm) 26 28.8 31.6 34.4 37.2 40 OUTPUT FREQUENCY (GHz) MUL TIPLIER PRODUCTS FUNDAMENTAL REJECTION VS. FREQUENCY

(PIN = +10 dBm) X ) -50 -20 3 FUN dBc -55 -25 N ( DAM

O X3 -60 -30 ENT ECTI

J -65 -35 AL RE -70 -40 RE AL X1 -75 -45 J ECTI ENT -80 -50 O DAM -85 -55 N ( dBc FUN

1 -90 -60 ) X 13 13.7 14.4 15 15.8 16.5 17.2 17.918.6 19.3 20 INPUT FREQUENCY (GHz)

NOTES: 1. Optional SMA or K type male/female connectors in input.

2. All dimensions shown in brackets [ ] are in millimeters.

408

ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MAX2M300500

ELECTRICAL SPECIFICATIONS Input frequency range 15 – 25 GHz Output frequency range 30 – 50 GHz Input power range 8 – 12 dBm Harmonic rejection Fundamental 20 dBc typical Odd harmonic 20 dBc typical

OUTPUT POWER VS. FREQUENCY 16 15 14 13 12 11 OUTLINE DRAWING 10 MAX2K OUTPUT POWER (dBm) 9 30 32 34 36 38 40 42 44 46 48 50 .15 .131 OUTPUT FREQUENCY (GHz) [3.81] [3.33] +VDC

.06 MOUNTING FUNDAMENTAL REJECTION VS. FREQUENCY [1.52] SURFACE INPUT (PIN = +10 dBm) -20 .363 OUTPUT [9.35] TIPLIER PRODUCTS -25 X1 .613 .85 [15.57] -30 [21.59]

MUL X3 -35 -40 -45 -50 .200 X2 Ø.079 [2.01] [5.08] REJECTION (dBc) -55 X2 .38 .43 [9.65] MOUNTING HOLES [10.92] .31 -60 [7.87] 15 16 17 18 19 20 21 22 23 24 25

INPUT FREQUENCY (GHz) NOTES: 1. Optional input connectors SMA, K or output connectors V type male/female.

2. Optional waveguide output available, please contact MITEQ.

3. All dimensions shown in brackets [ ] are in millimeters.

409 ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MAX2M360500

ELECTRICAL SPECIFICATIONS Input frequency range 18 – 25 GHz Output frequency range 36 – 50 GHz Input power range 10 – 15 dBm nominal Harmonic rejection Fundamental 20 dBc typical Odd harmonic 20 dBc typical

OUTPUT POWER VS. FREQUENCY

) 16 m 15 dB 14

ER ( 13 W

O OUTLINE DRAWING 12 11 MAX2K 10 UTPUT P

O 9 .15 .131 +VDC MUL 36 38.8 41.6 42 44.4 46 48 50 [3.81] [3.33]

OUTPUT FREQUENCY (GHz) .06 MOUNTING TIPLIER PRODUCTS [1.52] SURFACE INPUT

.363 FUNDAMENTAL REJECTION VS. FREQUENCY OUTPUT [9.35] (PIN = +10 dBm) .613 .85 [15.57] -15 [21.59] -20 ) -25 dBc -30

N ( -35 .200 O [5.08] -40 X2 .38 .43 X2 Ø.079 [2.01] [9.65] [10.92] MOUNTING HOLES -45 .31 ECTI [7.87] J -50

RE -55 -60 NOTES: 18 19.4 20.8 21 22.2 23.6 24 25 1. Optional input connectors SMA, K or INPUT FREQUENCY (GHz) output connectors V type male/female.

2. Optional waveguide output available, please contact MITEQ.

3. All dimensions shown in brackets [ ] are in millimeters.

410 ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MAX2M390440-20P

ELECTRICAL SPECIFICATIONS Input frequency range 19.5 – 22 GHz Output frequency range 39 – 44 GHz minimum Input power range 8 – 12 dBm nominal Harmonic rejection Fundamental 20 dBc minimum Odd harmonic 20 dBc minimum

OUTPUT POWER VS. FREQUENCY

) 26 25

dBm 24 OUTLINE DRAWING 23 22 ER ( 21 W MAX2L 20 19 18 16 17 X2 .076 [1.93] 15 HOLE THRU OUTPUT PO 14 .15 .210 [3.81] [5.33] 39 39.5 40 40.5 41 41.5 42 42.5 43 43.5 44 +VDC .06 [1.52] MOUNTING OUTPUT FREQUENCY (GHz) INPUT SURFACE

.368 FUNDAMENTAL REJECTION VS. FREQUENCY OUTPUT [9.35] .613 TIPLIER PRODUCTS (P = +10 dBm) .85 [15.57] IN [21.59]

MUL -20 -25 )

c -30 -35 -VDC dB -40 GND .200 .38 .51 [5.08] -45 [9.65] [12.95] ON (

I -50 .33 -55 [8.38]

ECT -60

J .12 [3.05] -65 MOUNTING SURFACE

RE -70 -75 -80 19.50 19.75 20.00 20.25 20.50 20.75 21.00 21.25 21.50 21.75 22.00 INPUT FREQUENCY (GHz)

NOTES: 1. Optional input connectors SMA, K or output connectors K or V type male.

2. Optional waveguide output available, please contact MITEQ.

3. All dimensions shown in brackets [ ] are in millimeters.

411 ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MAX2M020040

ELECTRICAL SPECIFICATIONS Input frequency range 1 – 2 GHz minimum Output frequency range 2 – 4 GHz minimum Input power range 8 – 12 dBm nominal Conversion loss 0 dB typical Optional input/output power MAX2J020040 3–8 dBm MAX2H020040 12–16 dBm MAX2V020040 16–20 dBm Harmonic rejection Fundamental 20 dB typical Odd harmonic 20 dB typical DC voltage/current +5 volts @ 95 mA typical

OUTPUT POWER VS. FREQUENCY OUTLINE DRAWING ) 17 MAX2A2MX2D dBm 15 ER (

13 MUL POW T 11 TIPLIER PRODUCTS U

TP 9 U

O 2 2.4 2.8 3.2 3.6 4 2.24 [56.90] SMA TYPE FREQUENCY (GHz) .08 [2.03] 2.085 [52.959] FEMALE .36 [9.14] RF OUTPUT .14 [3.56] .08 [2.03] .49 [12.45] .830 .98 SMA TYPE [21.08][24.89] FUNDAMENTAL REJECTION VS. FREQUENCY FEMALE RF INPUT (PIN = +10 dBm) 45 GROUND +5 V .11 [2.79]

) 1.60 [40.64] 1.87 [47.50] dB 40 N (

O 35 I T

EC 30 J

RE 25 NOTE: AL

T 20 1. All dimensions shown in brackets [ ] are in millimeters. EN 15 DAM 10 FUN 5 2 2.4 2.8 3.2 3.6 4 FREQUENCY (GHz)

412 413 MULTIPLIER PRODUCTS

FUNDAMENTAL REJECTION (dB) OUTPUT POWER (dBm) Cvlaecret+5volts@95mAtypical DC voltage/current Harmonic rejection 0dBtypical 8–12dBmnominal Optional input/outputpower 4–8GHzminimum Conversion loss 2–4GHzminimum Input powerrange Output frequencyrange Input frequencyrange 11 13 15 17 10 15 20 25 30 35 40 45 9 5 d amnc20dBtypical 20dBtypical 16–20dBm 12–16dBm Odd harmonic 3–8dBm Fundamental MAX2V040080 MAX2H040080 MAX2J040080 . . . . 8 7.2 6.4 5.6 4.8 4 . . . . 8 7.2 6.4 5.6 4.8 4 UDMNA EETO VS.FREQUENCY REJECTION FUNDAMENTAL ELECTRICAL SPECIFICATIONS UPTPWRVS.FREQUENCY OUTPUT POWER FREQUENCY (GHz) FREQUENCY (GHz) (P IN = +10dBm) CIEFEUNYDOUBLERS(CONT.) FREQUENCY ACTIVE MODEL: MAX2M040080 NOTE: SMA .08 [2.03] RF FEMALE .08 [2.03] INPUT TYPE GROUND .Alldimensionsshowninbrackets[]aremillimeters. 1. 1.60 [40.64] ULN DRAWING OUTLINE 1.87 [47.50] 2.085 [52.959] 2.24 [56.90] MAX2A2 MX2D +5 V [21.08] .830 RF FEMALE SMA OUTPUT TYPE [24.89] .98 .11 [2.79] .36 [9.14] .14 [3.56] [12.45] .49

ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: SYS2J060120

ELECTRICAL SPECIFICATIONS Input frequency range 3 – 6 GHz minimum Output frequency range 6 – 12 GHz minimum Input power range 5 dBm Output level +12 dB minimum Input harmonic rejection Fundamental -20 dB typical Odd harmonic -20 dB typical DC voltage/current +5/120

OUTPUT POWER VS. FREQUENCY OUTLINE DRAWING 17 ) 16 157637 15 dBm 14 ER ( 13 MUL 0.375 12 4X Ø.100 [Ø2.54] [9.525] POW

1.100 [27.94] TIPLIER PRODUCTS 11 MOUNTING HOLES TYP. T

U 10

TP 9 0.590 0.740 U 8 [18.796] O [14.986] 7 6000 6500 7000 7500 8000 8500 9000 9500 1000 10500110001150012000 INPUT OUTPUT FREQUENCY (MHz) 0.075 [1.905] 0.425 [10.795] 0.275 [6.985] HARMONIC REJECTION 0.200 [5.08] 0.200 [5.08] ) 10 0.370 0.370 [9.398] dBm 0 X1 X2 X3 [9.398] -10 ER ( -20

POW -30 T

U -40 0.410 [10.41] TP -50 U

O -60 2500 5000 7500 10000125001500017500 0.200 [5.08] FREQUENCY (MHz) 0.250 [6.35] 0.300 [7.62]

NOTE: 1. All dimensions shown in brackets [ ] are in millimeters.

414

415 MULTIPLIER PRODUCTS Cvlaecret+5/120 +12dBminimum 5dBm DC voltage/current 6–12GHzminimum 3–6GHzminimum Input harmonicrejection Output level Input powerrange Output frequencyrange Input frequencyrange OUTPUT POWER (dBm) OUTPUT POWER (dBm) -20dBtypical -20dBtypical Odd harmonic Fundamental -60 -50 -40 -30 -20 -10 10 11 12 13 14 15 16 17 10 7 8 9 0 0060 0070 0080 0090 00105001100011500 1000 9500 9000 8500 8000 7500 7000 6500 6000 ELECTRICAL SPECIFICATIONS 5050 5010000125001500017500 7500 5000 2500 UPTPWRVS.FREQUENCY OUTPUT POWER HARMONIC REJECTION X1 FREQUENCY (MHz) FREQUENCY (MHz) CIEFEUNYDOUBLERS FREQUENCY ACTIVE X2 X3 MODEL: SYS01J 12000 .344 [8.738] NOTE: [1.27] .222 [5.639] .050 IN .Alldimensionsshowninbrackets[]aremillimeters. 1. ULN DRAWING OUTLINE .460 [11.68] .050 [1.27] (CONT.) .92 [23.37] .820 [20.83] 162011 +V PC .222 [5.639] .04 [1.02] (4 PLACES) HOLES MOUNTING Ø.073 [Ø1.85] .44 [11.18] OUT MULTIPLIER PRODUCTS 416 RF OUTPUT +15 V GROUND .700 [17.78] .840 [21.34] .420 [10.67] .360 [9.14] .210 [5.33] MX2D MAX2B 1.463 [37.16] 1.100 [27.94] .900 [22.86] OUTLINE DRAWING .070 [1.78] 1.323 [33.60] 1. All dimensions shown in brackets [ ] are in millimeters. .070 [1.78] RF INPUT NOTE: MODEL: MAX2M080160 MODEL: ACTIVE FREQUENCY (CONT.) DOUBLERS = +10 dBm) IN (P FREQUENCY (GHz) FREQUENCY (GHz) 9.6 11.2 12.8 14.4 16 9.6 11.2 12.8 14.4 16 OUTPUT POWER VS. FREQUENCY ELECTRICAL SPECIFICATIONS ELECTRICAL 8 FUNDAMENTAL REJECTION VS. FREQUENCY 8 5 9 FundamentalOdd harmonic 20 dB typical 20 dB typical MAX2J080160MAX2H080160MAX2V080160 3–8 dBm 12–16 dBm 16–20 dBm 20 15 10 45 40 35 30 25

17 15 13 11

Harmonic rejection DC voltage/current +15 volts @ 160 mA typical Input power rangeConversion lossOptional input/output power 8 – 12 dBm nominal 0 dB typical Input frequency rangeOutput frequency range 4 – 8 GHz minimum 8 – 16 GHz minimum ) dB ( N O I T EC J RE AL T EN DAM FUN ) dBm ( ER POW T U TP U O ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: SYS2M130260

ELECTRICAL SPECIFICATIONS Input frequency range 6.5 – 13 GHz minimum FUNCTIONAL BLOCK DIAGRAM

Output frequency range 13 – 26 GHz minimum +V Input power range 8 – 12 dBm nominal Optional input/output power SYS2J130260 3–8 dBm IN X2 OUT SYS2H130260 12–16 dBm SYS2V130260 16–20 dBm Harmonic rejection Fundamental -20 dB typical Odd harmonic -20 dB typical DC voltage/current +15/100 SYS2V130260 +15/350

OUTLINE DRAWING 160833

1.40 [35.56] .24 .12 [3.05] 1.00 [25.40] [6.10] +15V S OUTPUT POWER VS. FREQUENCY

T OUT ) C IN .15 [3.81] .04 m U 17 .16 [4.06] [1.02] B D

d .11 [2.79] ( O 15 R R .44 P E .48 .19 [12.19] [11.18]

W [4.83] R 13 .70 O

E [17.78] I P

L .90 T

P 11 .45 0-80 X .10 [2.54] DP

I [22.86] U .38 MOUNTING HOLES

T [11.43] P [9.65] L T 9 TYP. .168 [42.67] .067 [1.702] DIA. THRU U U MOUNTING HOLES

O 13 15.6 18.2 20.8 23.4 26 .070 [1.778] DIA. THRU M (4 PLACES) MOUNTING HOLES FREQUENCY (GHz) (2 PLACES)

.18 [4.57] FUNDAMENTAL REJECTION VS. FREQUENCY .30 [7.62] (PIN = +10 dBm) 45 )

B 40 d

( .35

N [8.89] 35 O I .35 T TYPE SMA FEMALE FIELD [8.89] C 30 REPLACEABLE CONNECTORS E

J (2 PLACES) E

R 25

L .31 [7.87] A .18 [4.57] T 20 N

E SPACER MATERIAL: ALUMINUM M 15 MATERIAL: ALUMINUM

A FINISH: GOLD PLATED FINISH: IRRIDITE CL3 D

N 10 U F 5 13 15.6 18.2 20.8 23.4 26 NOTE: FREQUENCY (GHz) 1. All dimensions shown in brackets [ ] are in millimeters. 2 1 /

Tolerance as follows: 1 3 /

.xx = ±0.01 [.xx = ±0.25] 5 0

.xxx = ±0.005 [.xxx = ±0.13] : d e s i v e R

100 Davids Drive, Hauppauge, NY 11788 • TEL: (631) 439-9220 • FAX: (631) 436-7430 • 417 www.miteq.com ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MAX2M200400

ELECTRICAL SPECIFICATIONS Input frequency range 10 – 20 GHz Output frequency range 20 – 40 GHz Input power range 8 – 12 dBm Harmonic rejection Fundamental 20 dBc minimum Odd harmonic 20 dBc minimum

OUTPUT POWER VS. FREQUENCY

) 20 19

dBm 18 17

ER ( 16 3 W 15 3 3 33 OUTLINE DRAWING 14 3 3 13 MAX2K 12 3 11

OUTPUT PO 10 .15 .131 +VDC 20 22 24 26 28 30 32 34 36 38 40 [3.81] [3.33] MUL OUTPUT FREQUENCY (GHz) .06 MOUNTING [1.52] SURFACE TIPLIER PRODUCTS INPUT FUNDAMENTAL HARMONIC REJECTION .363 VS. FREQUENCY OUTPUT [9.35] (P = +10 dBm) .613 IN .85 [15.57] -20 [21.59]

) -25 c X3 -30 dB -35 X1 3 ON ( 3 .200 I -40 3 33 X2 Ø.079 [2.01] [5.08] 3 X2 .38 .43 -45 3 [9.65] [10.92] MOUNTING HOLES

ECT .31

J -50 [7.87] 3

RE -55 -60 10 11 12 13 14 15 16 17 18 19 20 INPUT FREQUENCY (GHz) NOTES: 1. Optional input connectors SMA, K or output connectors K or V type male.

2. Optional waveguide output available, please contact MITEQ.

3. All dimensions shown in brackets [ ] are in millimeters.

418

ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MAX2M200400-20P

OUTPUT POWER VS. FREQUENCY

) 26 25 24 dBm 23 22 ER ( 21

W OUTLINE DRAWING 20 19 18 MAX2L 17 16 15

OUTPUT PO 14 X2 .076 [1.93] HOLE THRU 20 22.5 25 27.5 30 32.5 35 37.5 40 .15 .210 [3.81] [5.33] +VDC .06 OUTPUT FREQUENCY (GHz) [1.52] MOUNTING INPUT SURFACE

.368 FUNDAMENTAL HARMONIC REJECTION OUTPUT [9.35] .613 .85 [15.57] VS. FREQUENCY [21.59] (PIN = +10 dBm)

TIPLIER PRODUCTS -20 -25 -VDC X3 GND .200 MUL

) -30 .38 .51 [5.08] c -35 [9.65] [12.95] .33

dB -40 [8.38] -45 X1 -55 .12 [3.05] ON ( I -50 MOUNTING SURFACE -60 ECT

J -65 -70 RE -75 -80 10 11 12 13 14 15 16 17 18 19 20 NOTES: 1. Optional input connectors SMA, K or output INPUT FREQUENCY (GHz) connectors K or V type male.

2. Optional waveguide output available, please contact MITEQ.

3. All dimensions shown in brackets [ ] are in millimeters.

419 ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MAX2M010060

ELECTRICAL SPECIFICATIONS Input frequency range 0.5 – 3 GHz minimum Output frequency range 1 – 6 GHz minimum Input power range 8 – 12 dBm nominal Conversion loss 0 dB typical Optional input/output power MAX2J010060 3–8 dBm MAX2H010060 12–16 dBm MAX2V010060 16–20 dBm Harmonic rejection Fundamental 20 dB typical Odd harmonic 20 dB typical DC voltage/current +5 volts @ 95 mA typical

OUTPUT POWER VS. FREQUENCY OUTLINE DRAWING 17 MAX2A2MX2D 15

13 MUL

11 TIPLIER PRODUCTS 9

OUTPUT POWER (dBm) 123456 FREQUENCY (GHz) 2.24 [56.90] SMA TYPE .08 [2.03] 2.085 [52.959] FEMALE .36 [9.14] RF OUTPUT .14 [3.56] .08 [2.03] .49 [12.45] .830 .98 FUNDAMENTAL REJECTION VS. FREQUENCY SMA TYPE [21.08][24.89] FEMALE (PIN = +10 dBm) RF INPUT 45 GROUND 1.60 [40.64] +5 V .11 [2.79] 40 1.87 [47.50]

20 NOTE: 1. All dimensions shown in brackets [ ] are in millimeters. 15

10 FUNDAMENTAL REJECTION (dB) 5 123456 FREQUENCY (GHz)

420 ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MAX2M030180

ELECTRICAL SPECIFICATIONS Input frequency range 1.5 – 9 GHz minimum Output frequency range 3 – 18 GHz minimum Input power range 8 – 12 dBm nominal Conversion loss 0 dB typical Optional input/output power MAX2J030180 3–8 dBm MAX2H030180 12–16 dBm MAX2V030180 16–20 dBm Harmonic rejection Fundamental 15 dB typical Odd harmonic 20 dB typical DC voltage/current +15 volts @ 160 mA typical

OUTLINE DRAWING OUTPUT POWER VS. FREQUENCY ) 17 MAX2B dBm 15 +15 V ER ( 1.100 [27.94] GROUND 13 .900 [22.86] POW

T 11 U

TP 9 .070 [1.78] U

O 3 6 9 12 15 18 .700 [17.78] FREQUENCY (GHz) RF INPUT

TIPLIER PRODUCTS RF FUNDAMENTAL REJECTION VS. FREQUENCY .070 [1.78] 1.323 [33.60] OUTPUT MUL (PIN = +10 dBm) 1.463 [37.16] 45

) .420 [10.67]

dB 40 N (

O 35 I .840 [21.34] T

EC 30 J

RE 25 .210 [5.33]

AL .360 [9.14] T 20 EN 15 DAM 10 FUN 5 NOTE: 3 6 9 12 15 18 1. All dimensions shown in brackets [ ] are in millimeters. FREQUENCY (GHz)

421

ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: MAX2M060260

ELECTRICAL SPECIFICATIONS Input frequency range 3 – 13 GHz minimum Output frequency range 6 – 26 GHz minimum Input power range 8 – 12 dBm nominal Conversion loss 0 dB typical Harmonic rejection Fundamental 12 dB typical Odd harmonic 15 dB typical

OUTPUT POWER VS. FREQUENCY 17

15 OUTLINE DRAWING 13 MAX2C 11

9 1.07 [27.18]

OUTPUT POWER (dBm) .73 [18.54] 6 10 14 18 22 26 MUL .49 [12.45] RF OUTPUT FREQUENCY (GHz) .070 [1.78] DIA. GROUND DC POWER TIPLIER PRODUCTS MOUNTING HOLES .43 [10.92] (TYP. 2 PLACES) .16 .11 [2.79] [4.06] FUNDAMENTAL REJECTION VS. FREQUENCY .28 [7.11] .070 [1.78] (PIN = +10 dBm) .70 .480 .500 [12.70] 45 [17.78] [12.19]

40 .27 [6.86] .100 [25.4] DIA. 131218 REF .210 [5.33] 35 RF INPUT MOUNTING HOLES .654 (TYP. 4 PLACES) 30 [16.61] 121623-5 REF. 2.19 [55.63] 25

20 .11 [2.79] TYPE SMA FIELD .19 [4.83] REPLACEABLE 15 .32 [8.13] FEMALE CONNECTOR (TYP. BOTH ENDS) 10

FUNDAMENTAL REJECTION (dB) .64 [16.26] 5 6 10 14 18 22 26 .20 [5.08] FREQUENCY (GHz) .31 [7.87] MOUNTING SURFACE

NOTE: 1. All dimensions shown in brackets [ ] are in millimeters.

422 ACTIVE FREQUENCY DOUBLERS (CONT.)

MODEL: SYS2J150450

ELECTRICAL SPECIFICATIONS OUTLINE DRAWING Input frequency range 7.5 – 22 GHz minimum 163640 Output frequency range 15 – 45 GHz minimum Requires regulated -5 V, 50 mA .560 [14.224] .160 [4.064] +15 V, 220 mA + V .240 [6.096] Input power range 3 dBm nominal .042 [1.067] Conversion gain 10 dB typical .260 [6.604] Harmonic rejection .520 .436 [13.208] [11.074] Fundamental -20 dB typical Odd harmonic -20 dB typical RF IN RF OUT .067 [1.702] DIA. THRU - V MOUNTING HOLES (4PLACES) TYPE "K" OR "SMA" FIELD .280 [7.112] REPLACEABLE FEMALE CONNECTOR, 2 PLACES CONVERSION GAIN VS. FREQUENCY .290 [7.366] .195 [4.953] 12 .38 .100 [2.54] [9.65] TYP. OPTIONAL SPACER PLATE 11

10 NOTES: 9 1. Unit’s mounting surface shall be attached to a heatsink capable of dissipating the devices power consumption 8 without exceeding the operating temperature limits. 2. Refer to the actual device specification sheet for bias 7 requirements. Negative bias input voltage (v-) may not 6 be included on certain models.

CONVERSION GAIN (dB) 3. Unless noted on the specification sheet, when negative TIPLIER PRODUCTS 5 bias is required, do not power the unit with positive bias for more than one second without the negative bias

MUL 4 16 2024 28 32 4036 44 being applied. 4. All dimensions shown in brackets [ ] are in millimeters. FREQUENCY (GHz)

FUNDAMENTAL REJECTION VS. FREQUENCY

50 FUNDAMENTAL REJECTION (dB) 55 16 2420 28 32 4036 44 FREQUENCY (GHz)

423 ACTIVE 2X FREQUENCY MULTIPLIER

MODEL: SYS2X1122

FEATURES • High fundamental rejection...... -50 dBc • Output power...... 0 dBm • RF output monitor • Packaging ...... Hermetically sealed

ELECTRICAL SPECIFICATIONS

INPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. RF frequency range GHz 9.5 11.5 RF VSWR 50 ohm reference Ratio 2.5:1 RF power range dBm -5 V+ bias voltage @ 250 mA max. VDC 9 16 V- bias voltage @ 15 mA max. VDC -9 -16

TRANSFER CHARACTERISTICS CONDITION UNITS MIN. TYP. MAX. MUL Output power dBm 0 Fundamental leakage Input dBc -50 TIPLIER PRODUCTS

OUTPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. RF frequency range GHz 19 23 RF VSWR 50 ohm reference Ratio 2.5:1 RF power dBm 0 RF monitor dBm -20

NOTE: Test data supplied at 25°C; MAXIMUM RATINGS fundamental rejection, output power and RF monitor. Specification temperature...... +25°C Operating temperature ...... -40 to +65°C OUTLINE DRAWING Storage temperature...... -65 to +95°C

0.75 MOUNTING SURFACE (SEE NOTE 1) [19.05] ADD SUFFIX TO OUTLINE DRAWING MODEL NO. OPTIONS 0.12 [3.05] WG (WR42) WR42 output waveguide

SMA FIELD S Single positive supply 0.11 0.250 [6.35] 0.197 REPLACEABLE [5.00] [2.79] 0.13 [3.30] 0.38 CONNECTOR [9.65] (TYP. 3 PLACES) TYP, 0.250 [6.35]

V+ CPL 0.35 [8.81] 0.700 1.200 0.980 TYP. [30.48] Fundamental [17.78] IN OUT [24.89] 1.20 2X Fundamental [30.48] -V GND HARMONICS RF Monitor 20 10 0.15 [3.81] 1.030 [26.16] 2X Ø0.104 [2.64] 0 0.27 -10 0.35 [6.86] [8.89] -20 0.11 [2.79] TYP. -30 0.12 [3.05] -40 -50 0.077 [19.56] 0.55 [13.97] OPTIONAL SPACER PLATE -60 -70 -80

NOTES: 1. Unit’s mounting surface shall be attached to a heatsink capable of OUTPUT POWER (dBm) dissipating the devices power consumption without exceeding the -90 -100 operating temperature limits. 9.59.75 10 10.25 10.510.75 11 11.25 11.5 2. All dimensions shown in brackets [ ] are in millimeters. INPUT FREQUENCY (GHz)

424 ACTIVE 2X FREQUENCY MULTIPLIER (CONT.)

MODEL: SYS2X1326

FEATURES • Fundamental rejection...... -70 dBc • Output power...... +16 dBm • Packaging ...... Hermetically sealed

ELECTRICAL SPECIFICATIONS

INPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. RF frequency range GHz 10 13.25 RF VSWR 50 ohm reference Ratio 2.5:1 RF power range dBm +10 +12 V+ bias voltage @ 250 mA max. VDC 9 16 V- bias voltage @ 15 mA max. VDC -9 -16

TRANSFER CHARACTERISTICS CONDITION UNITS MIN. TYP. MAX. Output power dBm +16 Fundamental leakage fo 21–26.5 GHz Input dBc -70 -50 fo 20–21.5 GHz -40 -25

OUTPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. RF frequency range GHz 20 26.5 RF VSWR 50 ohm reference Ratio 2.5:1 TIPLIER PRODUCTS

MUL MAXIMUM RATINGS ADD SUFFIX TO Specification temperature...... +25°C MODEL NO. OPTIONS Operating temperature ...... -40 to +65°C WG WR42 waveguide adaptor Storage temperature...... -65 to +95°C S Single positive supply

NOTE: Test data supplied at 25°C; fundamental rejection and output power. OUTLINE DRAWING

0.62 [15.75] 0.38 MOUNTING SURFACE (SEE NOTE 1) [9.65]

0.13 [3.30] 0.13 [3.30]

0.900 [22.86] 0.375 TYPE 'K' OR 2.9mm [9.53] FIELD REPLACEABLE 0.114 [2.90] 0.070 0.230 FEMALE 0.225 [5.72] [1.78] [5.84] CONNECTOR

0.343 [8.71] GND V+ 0.547 0.687 [13.89] IN OUT [17.45] -V

TYPE 'SMA' FIELD 0.311* [7.90] REPLACEABLE X2Ø .100 [2.54] THRU MTG. HOLE 0.200* [5.08] FEMALE CONNECTOR 0.440 OPTIONAL GROUND TERMINAL [11.18]

NOTES: 1. Unit’s mounting surface shall be 0.52 [13.21] attached to a heatsink capable of 0.28 [7.11] dissipating the devices power consumption without exceeding 0.13 [3.30] 0.13 [3.30] the operating temperature limits. 2. All dimensions shown in brackets [ ] OPTIONAL SPACER PLATE* P/N:140918 0.086* [2.18] are in millimeters.

425 ACTIVE 2X FREQUENCY MULTIPLIER (CONT.)

MODEL: SYS2X2040

FEATURES • RF input...... 10 to 20 GHz • RF output ...... 20 to 40 GHz • Packaging ...... Hermetically sealed

ELECTRICAL SPECIFICATIONS

INPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. RF frequency range GHz 10 20 RF VSWR 50 ohm reference Ratio 3:1 RF power range dBm +9 +13 V+ bias voltage @ 250 mA max. VDC 9 16 V- bias voltage @ 15 mA max. VDC -9 -16

TRANSFER CHARACTERISTICS CONDITION UNITS MIN. TYP. MAX. MUL Output power dBm +12 +15 Fundamental leakage Input dBc -16 -5 TIPLIER PRODUCTS

OUTPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. RF frequency range GHz 20 40 RF VSWR 50 ohm reference Ratio 2.75:1 RF power dBm +15

NOTE: Test data supplied at 25°C; MAXIMUM RATINGS fundamental rejection and output power. Specification temperature...... +25°C Operating temperature ...... -40 to +65°C OUTLINE DRAWING Storage temperature...... -65 to +95°C

0.62 [15.75] 0.38 MOUNTING SURFACE (SEE NOTE 1) [9.65] ADD SUFFIX TO MODEL NO. OPTION 0.13 [3.30] 0.13 [3.30] S Single positive supply

0.900 [22.86] 0.375 TYPE 'K' OR 2.9mm [9.53] FIELD REPLACEABLE 0.114 [2.90] 0.070 0.230 FEMALE 0.225 [5.72] [1.78] [5.84] CONNECTOR

0.343 [8.71] GND V+ 0.547 0.687 [13.89] IN OUT [17.45] -V Fundamental HARMONICS 2X Fundamental TYPE 'SMA' FIELD 0.311* [7.90] REPLACEABLE X2Ø .100 [2.54] THRU MTG. HOLE 0.200* [5.08] FEMALE CONNECTOR 0.440 OPTIONAL GROUND TERMINAL 20 [11.18]

0.52 [13.21] 10 0.28 [7.11] 0 0.13 [3.30] 0.13 [3.30] -10

OPTIONAL SPACER PLATE* P/N:140918 0.086* [2.18] -20 AND HARMONIC -30 FUNDAMENTAL (dBm) NOTES: 1. Unit’s mounting surface shall be attached to a heatsink capable of OUTPUT POWER (dBc), -40 dissipating the devices power consumption without exceeding the 1011 12 13 1415 16 17 18 2019 operating temperature limits. INPUT FREQUENCY (GHz) 2. All dimensions shown in brackets [ ] are in millimeters.

426 427 MULTIPLIER PRODUCTS OPTIONAL SPACERPLATE akgn ...... Hermetically sealed ...... Packaging • RFoutputmonitor • +10dBm Outputpower...... • -70dBc Highfundamentalrejection...... • FEATURES OE:1 Unit’s mounting surfaceshallbeattachedtoaheatsinkcapableof 1. NOTES: UPTPRMTR ODTO NT I.TP MAX. TYP. MIN. UNITS MAX. CONDITION TYP. MIN. MAX. UNITS TYP. MIN. CONDITION UNITS OUTPUT PARAMETERS CONDITION TRANSFER CHARACTERISTICS INPUT PARAMETERS 0.11 [2.79]TYP. Fmntrdm-20 0 26.48 dBm dBm 2.5:1 -50 +10 22.48 -70 +3 GHz -16 Ratio 16 dBm 50ohmreference 13.24 dBc -5 2.5:1 -9 dBm 9 11.24 Input VDC GHz VDC max. @15mA Ratio max. @250mA 50ohmreference RF monitor RF power RF VSWR RF frequencyrange Fundamental leakage Output power V- bias voltage V+ biasvoltage RF powerrange RF VSWR RF frequencyrange OE Test datasuppliedat25°C; NOTE: 0.077 [19.56] .Alldimensionsshown inbrackets[]aremillimeters. 2. [30.48] 1.20 operating temperature limits. dissipating thedevicespowerconsumption withoutexceedingthe [17.78] fundamental rejection,outputpowerandRFmonitor. 0.700 [6.35] 0.250 [2.79] 0.11 ULN DRAWING OUTLINE IN 0.55 [13.97] [8.89] 0.35 ACTIVE 2XFREQUENCYMULTIPLIER (CONT.) [19.05] 0.75 -V +CPL V+ 0.13 [3.30] 1.030 [26.16] 1.030 0.250 [6.35] GND OUT MOUNTING SURFACE(SEENOTE 1) [9.65] TYP, 0.38 2X Ø0.104[2.64] ELECTRICAL SPECIFICATIONS [24.89] 0.12 [3.05] 0.980 MODEL: SYS2X1224 0.12 [3.05] [8.81] [5.00] 0.197 TYP. 0.35 [6.86] 0.27 [30.48] 1.200 0.15 [3.81] (TYP. 3PLACES) CONNECTOR REPLACEABLE SMA FIELD trg eprtr...... -65 to +95°C Storage temperature...... -40to+65°C ...... Operating temperature +25°C Specification temperature...... RATINGS MAXIMUM Singlepositivesupply WR42 outputwaveguide OPTIONS S WG (WR42) MODEL NO. ADD SUFFIXTO OUTPUT POWER (dBm) -100 -90 -80 -70 -60 -50 -40 -30 -20 -10 10 20 0 11 12.5 12 11 151 13.5 13 11.5 INPUT FREQUENCY (GHz) HARMONICS 2X Fundamental Fundamental MULTIPLIER PRODUCTS 428 18 Fundamental 2X Fundamental 3X Fundamental HARMONICS INPUT FREQUENCY (GHz) 14 17 19 20 13 15 16 0 25

-25 -50 -75

-100 -125 -150 OUTPUT POWER (dBc) POWER OUTPUT ADD SUFFIX TO MODEL NO.S OPTION supply Single positive MAXIMUM RATINGS Specification temperature...... +25°C Operating temperature ...... -40 to +65°C Storage temperature...... -65 to +95°C 4X #4–40 UNC-2B 50 ohm reference Ratio 2.5:1 COVER FLANGE 0.100 [2.54] 1.25 [31.75] CONFORMS TO WR28 0.80 4X .100 [2.54] DIA. THRU 1.050 [20.32] [26.67] ELECTRICAL SPECIFICATIONS MODEL: SYS2X2640WG MODEL: MOUNTING SURFACE (SEE NOTE 1) OPTIONAL GROUND TERMINAL 1.525 [38.735] 0.100 [2.54] 1.936 [49.174] ±.02 [0.51] 1.936 [49.174] ±.02 ±.02 0.38 [0.51] [9.65] ACTIVE 2X FREQUENCY MULTIPLIER (CONT.) MULTIPLIER FREQUENCY 2X ACTIVE OUTLINE DRAWING 0.43 [10.92] 2X .38 [9.65] FIELD 2X .62 [15.75] FEMALE 2X .45 [11.43] TYPE "SMA" CONNECTOR REPLACEABLE fundamental rejection and output power. dissipating the devices power consumption without exceeding the operating temperature limits. 0.125 [3.175] 2. [ ] are in millimeters. All dimensions shown in brackets NOTE: data supplied at 25°C; Test RF power dBm +15 Fundamental leakageThird-harmonic leakageRF frequency rangeRF VSWR Input Input dBc dBc 50 ohm reference Ratio GHz -80 -30 26 -50 -15 2.5:1 40 RF power rangeV+ bias voltage bias voltageV- Output power mA @ 250 max.mA @ 15 max. VDC VDC 9 dBm -9 +9 dBm 16 -16 +13 +13 +15 RF frequency rangeRF VSWR GHz 13 20 0.62 OUTPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. TRANSFER CHARACTERISTICS CONDITION UNITS MIN. TYP. MAX. INPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. [15.75] NOTES: 1. attached to a heatsink capable of mounting surface shall be Unit’s • Fundamental rejection...... -80 dBc • Output power...... +15 dBm • Packaging ...... Hermetically sealed FEATURES 429 MULTIPLIER PRODUCTS 0.311* [7.90] 0.200* [5.08] akgn ...... Hermetically sealed ...... Packaging • +17dBm Outputpower...... • -70dBc Highfundamentalrejection...... • FEATURES 0.225 [5.72] 0.114 [2.90] OE:1 Unit’s mounting surfaceshallbeattachedtoaheatsinkcapableof 1. NOTES: UPTPRMTR ODTO NT I.TP MAX. TYP. MIN. UNITS MAX. CONDITION TYP. MIN. MAX. UNITS TYP. MIN. CONDITION UNITS OUTPUT PARAMETERS CONDITION TRANSFER CHARACTERISTICS INPUT PARAMETERS FfeunyrneGz28 2.5:1 -60 +17 -60 -70 GHz +14 Ratio -16 +12 16 dBm 50ohmreference dBc 14 dBc 2.5:1 -9 dBm 9 Input Input VDC GHz VDC max. @15mA Ratio max. @220mA 50ohmreference RF VSWR RF frequencyrange Third-harmonic leakage Fundamental leakage Output power V- bias voltage V+ biasvoltage RF powerrange RF VSWR RF frequencyrange OE Test datasuppliedat25°C; NOTE: .Alldimensionsshown inbrackets[]aremillimeters. 2. OPTIONAL SPACERPLATE*P/N:140918 operating temperature limits. dissipating thedevicespowerconsumption withoutexceedingthe fundamental rejectionandoutputpower. [8.71] 0.343 TYPE 'SMA'FIELD REPLACEABLE CONNECTOR ULN DRAWING OUTLINE 0.13 [3.30] FEMALE [1.78] 0.070 ACTIVE 2XFREQUENCYMULTIPLIER (CONT.) 0.13 [3.30] [13.89] 0.547 [5.84] 0.230 [7.11] 0.52 [13.21] 0.28 IN [9.65] 0.62 [15.75] 0.38 0.900 [22.86] -V GND [11.18] 0.440 ELECTRICAL SPECIFICATIONS V+ MODEL: SYS2X1428 OUT 0.086* [2.18] MOUNTING SURFACE(SEENOTE1) OPTIONAL GROUNDTERMINAL [9.53] 0.375 X2Ø .100[2.54]THRUMTG.HOLE 0.13 [3.30] 0.13 [3.30] [17.45] 0.687 CONNECTOR FEMALE FIELD REPLACEABLE TYPE 'K'OR2.9mm trg eprtr...... -65 to +95°C Storage temperature...... -40to+65°C ...... Operating temperature +25°C Specification temperature...... RATINGS MAXIMUM OUTPUT POWER Very highfundamental (dBm) Singlepositivesupply WR28 outputwaveguide OPTIONS VH S WG (WR28) MODEL NO. ADD SUFFIXTO -80 -70 -60 -50 -40 -30 -20 -10 10 20 0 351. 13.8 13.7 13.5 361. 4114.2 14.1 13.9 13.6 INPUT FREQUENCY (GHz) HARMONICS rejection (80dBc) 41. 14.514.4 14.3 14 3X Fundamental 2X Fundamental Fundamental MULTIPLIER PRODUCTS 430 Fundamental 2X Fundamental 3X Fundamental RF Monitor 15 15.3 15.515.4 HARMONICS INPUT FREQUENCY (GHz) 14.6 14.9 15.1 15.2 14.5 14.7 14.8 0 30 20 10

-10 -20 -30 -40 -50 -60 -70 -80 -90

-100 OUTPUT POWER (dBm) POWER OUTPUT ADD SUFFIX TO MODEL NO.WG (WR42) S OPTIONS WR42 output waveguide supply Single positive MAXIMUM RATINGS Specification temperature...... +25°C Operating temperature ...... -40 to +65°C Storage temperature...... -65 to +95°C SMA FIELD REPLACEABLE CONNECTOR (TYP. 3 PLACES) 0.15 [3.81] 1.200 [30.48] 0.27 [6.86] 0.35 TYP. 0.197 [5.00] [8.81] 0.12 [3.05] 0.980 0.12 [3.05] [24.89] MODEL: SYS2X1530 MODEL: ELECTRICAL SPECIFICATIONS 2X Ø0.104 [2.64] 0.38 TYP, [9.65] MOUNTING SURFACE (SEE NOTE 1)MOUNTING SURFACE (SEE NOTE OUT GND 0.250 [6.35] 1.030 [26.16] 0.13 [3.30] V+ CPL -V 0.75 [19.05] ACTIVE 2X FREQUENCY MULTIPLIER (CONT.) MULTIPLIER FREQUENCY 2X ACTIVE 0.35 [8.89] 0.55 [13.97] IN OUTLINE DRAWING 0.11 [2.79] 0.250 [6.35] 0.700 [17.78] fundamental rejection, output power and RF monitor. fundamental rejection, output power and dissipating the devices power consumption without exceeding the operating temperature limits. 1.20 [30.48] 2. [ ] are in millimeters. All dimensions shown in brackets 0.077 [19.56] NOTE: data supplied at 25°C; Test 0.11 [2.79] TYP. RF monitor dBm -2 Fundamental leakageThird-harmonic leakageRF frequency rangeRF VSWR Input Input dBc dBc 50 ohm reference Ratio GHz -90 -80 -75 2.5:1 30 RF power rangeV+ bias voltage bias voltageV- Output power mA @ 450 max.mA @ 15 max. VDC VDC 9 dBm -9 -20 dBm 16 -16 +18 +20 RF frequency rangeRF VSWR 50 ohm reference Ratio GHz 2.5:1 15 OUTPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. TRANSFER CHARACTERISTICS CONDITION UNITS MIN. TYP. MAX. INPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. NOTES: 1. be attached to a heatsink capable of mounting surface shall Unit’s OPTIONAL SPACER PLATE FEATURES •rejection...... High fundamental -90 dBc • Output power...... +20 dBm • RF output monitor • Packaging ...... Hermetically sealed 431 MULTIPLIER PRODUCTS 0.311* [7.90] 0.200* [5.08] akgn ...... Hermetically sealed ...... Packaging • +18dBm Outputpower...... • -50dBc Highfundamentalrejection...... • FEATURES 0.225 [5.72] 0.114 [2.90] OE:1 Unit’s mounting surfaceshallbeattachedtoaheatsinkcapableof 1. NOTES: UPTPRMTR ODTO NT I.TP MAX. TYP. MIN. UNITS MAX. CONDITION TYP. MIN. MAX. UNITS TYP. MIN. CONDITION UNITS OUTPUT PARAMETERS CONDITION TRANSFER CHARACTERISTICS INPUT PARAMETERS FfeunyrneGz3 435 34 2.5:1 32 +18 -50 +13 GHz -16 Ratio +12 16 dBm 17.5 50ohmreference dBc 17 -9 dBm 16 9 Input VDC GHz VDC max. @15mA max. @250mA RF VSWR RF frequencyrange Fundamental leakage Output power V- bias voltage V+ biasvoltage RF powerrange RF VSWR RF frequencyrange OE Test datasuppliedat25°C; NOTE: .Alldimensionsshown inbrackets[]aremillimeters. 2. OPTIONAL SPACERPLATE*P/N:140918 operating temperaturelimits. dissipating thedevicespowerconsumption withoutexceedingthe fundamental rejectionandoutputpower. [8.71] 0.343 TYPE 'SMA'FIELD REPLACEABLE CONNECTOR ULN DRAWING OUTLINE 0.13 [3.30] FEMALE [1.78] 0.070 ACTIVE 2XFREQUENCYMULTIPLIER (CONT.) 0.13 [3.30] [13.89] 0.547 [5.84] 0.230 [7.11] 0.52 [13.21] 0.28 IN [9.65] 0.62 [15.75] 0.38 0.900 [22.86] -V GND [11.18] 0.440 ELECTRICAL SPECIFICATIONS V+ MODEL: SYS2X1734 OUT 0.086* [2.18] MOUNTING SURFACE(SEENOTE1) OPTIONAL GROUNDTERMINAL [9.53] 0.375 X2Ø .100[2.54]THRUMTG.HOLE 0.13 [3.30] 0.13 [3.30] [17.45] 0.687 0omrfrneRto2.5:1 Ratio 50 ohmreference CONNECTOR FEMALE FIELD REPLACEABLE TYPE 'K'OR2.9mm trg eprtr...... -65to +95°C Storage temperature...... -40to+65°C ...... Operating temperature +25°C Specification temperature...... RATINGS MAXIMUM OUTPUT POWER (dBm) Singlepositivesupply WR28outputwaveguide OPTIONS S WG MODEL NO. ADD SUFFIXTO -100 -90 -80 -70 -60 -50 -40 -30 -20 -10 10 20 30 0 551. 17 16.5 15.5 61. 18 17.5 16 INPUT FREQUENCY (GHz) HARMONICS 2X Fundamental Fundamental MULTIPLIER PRODUCTS 432 Fundamental 2X Fundamental RF Monitor 17.525 17.6 HARMONICS INPUT FREQUENCY (GHz) 17.425 17.5 17.55 17.575 17.4 17.45 17.475 0 30 20 10 -10 -20 -30 -40 -50 -60 -70 -80 -90

-100 ADD SUFFIX TO MODEL NO.WG (WR42) S OPTIONS WR42 output waveguide (dBm) supply Single positive POWER OUTPUT MAXIMUM RATINGS Specification temperature...... +25°C Operating temperature ...... -40 to +65°C Storage temperature...... -65 to +95°C SMA FIELD REPLACEABLE CONNECTOR (TYP. 3 PLACES) 50 ohm reference Ratio 2.5:1 0.15 [3.81] 1.200 [30.48] 0.27 [6.86] 0.35 TYP. 0.197 [5.00] [8.81] 0.12 [3.05] MODEL: SYS2X1735 MODEL: 0.980 0.12 [3.05] [24.89] ELECTRICAL SPECIFICATIONS 2X Ø0.104 [2.64] 0.38 TYP, [9.65] MOUNTING SURFACE (SEE NOTE 1)MOUNTING SURFACE (SEE NOTE OUT GND 0.250 [6.35] 1.030 [26.16] 0.13 [3.30] V+ CPL -V 0.75 [19.05] ACTIVE 2X FREQUENCY MULTIPLIER (CONT.) MULTIPLIER FREQUENCY 2X ACTIVE 0.35 [8.89] 0.55 [13.97] IN OUTLINE DRAWING 0.11 [2.79] 0.250 [6.35] 0.700 fundamental rejection, output power and RF monitor. fundamental rejection, output power and [17.78] dissipating the devices power consumption without exceeding the operating temperature limits. 1.20 2. [ ] are in millimeters. All dimensions shown in brackets [30.48] 0.077 [19.56] NOTE: data supplied at 25°C; Test Fundamental leakageRF frequency rangeRF VSWRRF monitor Input dBc 50 ohm reference Ratio GHz -70 -50 2.5:1 dBm 35 -2 RF power rangeV+ bias voltage bias voltageV- Output power @ 450 mA max. @ 15 mA max. VDC VDC 9 dBm -9 -20 dBm 16 -16 +18 RF frequency rangeRF VSWR GHz 17.5 0.11 [2.79] TYP. OUTPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. TRANSFER CHARACTERISTICS CONDITION UNITS MIN. TYP. MAX. INPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. NOTES: 1. attached to a heatsink capable of mounting surface shall be Unit’s FEATURES •rejection...... High fundamental -70 dBc • Output power...... +18 dBm • RF output monitor • Packaging ...... Hermetically sealed OPTIONAL SPACER PLATE ACTIVE FREQUENCY TRIPLERS

MODEL: SYS3J042072

ELECTRICAL SPECIFICATIONS Input frequency range 1.4 – 2.4 GHz Output frequency range 4.2 – 7.2 GHz Input power range 4 dBm Output level +12 dB typical Harmonic rejection Input -20 dB typical Output -15 dB typical Input, output VSWR 2.5:1 typical DC voltage/current +5/150

OUTPUT POWER VS. FREQUENCY OUTLINE DRAWING (PIN = +10 dBm) 157637 14 13 0.375 12 4X Ø.100 [Ø2.54] [9.525] 1.100 [27.94] TYP. 11 MOUNTING HOLES 10 0.740 9 0.590 [14.986] [18.796] 8

OUTPUT POWER (dBm) 7 INPUT OUTPUT 4000 4500 5000 5500 6000 6500 7000 0.075 [1.905] 0.425 [10.795] FREQUENCY (MHz) 0.275 [6.985] TIPLIER PRODUCTS 0.200 [5.08] 0.200 [5.08] MUL HARMONIC REJECTION 15 0.370 0.370 [9.398] 10 X3 [9.398] 5 X1 X2 X6 0 -5 X4 X5 X9 -10 X7 -15 -20 0.410 [10.41] -25 X8 -30 -35 0.200 [5.08] OUTPUT POWER (dBm) 2500 5000 7500 10000125001500017500 0.250 [6.35] 0.300 [7.62] FREQUENCY (MHz)

NOTE: 1. All dimensions shown in brackets [ ] are in millimeters.

433 ACTIVE FREQUENCY TRIPLERS (CONT.)

MODEL: SYS02J

ELECTRICAL SPECIFICATIONS FUNCTIONAL BLOCK DIAGRAM Input frequency range 1.4 – 2.4 GHz Output frequency range 4.2 – 7.2 GHz Input power range 4 dBm Output level +12 dB typical X3 Harmonic rejection Input -20 dB typical Output -15 dB typical Input, output VSWR 2.5:1 typical DC voltage/current +5/150

OUTPUT POWER VS. FREQUENCY OUTLINE DRAWING (PIN = +10 dBm) )

m 14 B d

( 13

R 12 E

W 11 M O P 10 U L T Ø.073 [Ø1.85] 9 T U

MOUNTING I P P 8 .050 .820 [20.83] HOLES T [1.27] L I

U .050 [1.27] (4 PLACES) 7 E O 4000 4500 5000 5500 6000 6500 7000 R .222 [5.639] P R

FREQUENCY (MHz) O .344 [8.738] .44 [11.18] D U C

HARMONIC REJECTION T

IN S

) 15 OUT .460 [11.68] +V m 10 X3 PCB B 5 X1 X6 .04 [1.02] d X2 ( 0 R -5 X4 X5 E X9 .92 [23.37] W -10 X7

O -15 P -20 T -25 X8 U

P -30 T -35 U O 2500 5000 7500 10000125001500017500 NOTE: FREQUENCY (MHz) 1. All dimensions shown in brackets [ ] are in millimeters.

4 1 1 / 6 2 / 3 0 : d e s i v e R 4 3 4 / B 4 3 - C

100 Davids Drive, Hauppauge, NY 11788 • TEL: (631) 439-9220 • FAX: (631) 436-7430 • www.miteq.com 434 PASSIVE FREQUENCY TRIPLERS

MODEL: MX3M320400

ELECTRICAL SPECIFICATIONS Input frequency range 10.66 – 13.33 GHz Output frequency range 32 – 40 GHz Input power range 8 – 12 dBm Harmonic rejection Fundamental -55 dBc typical Odd harmonic -55 dBc typical

OUTPUT POWER VS. FREQUENCY

-1 -2 OUTLINE DRAWING -3 -4 -5 MXF -6 -7 -8 .06 -9 [1.52] .15 .131 MOUNTING -10 INPUT [3.81] [3.33] SURFACE OUTPUT POWER (dBm) -11 RF 32.4 33.6 34.8 36 37.2 38.4 39.6 40.8 OUTPUT .368 [9.35] .37 .613 [9.40] .85 [15.57] OUTPUT FREQUENCY (GHz) [.21.59]

FUNDAMENTAL HARMONIC REJECTION

TIPLIER PRODUCTS VS. FREQUENCY .200 x2 .38 X2 Ø .079 [2.01] [5.08] 0 [9.65] .43 MOUNTING HOLES [10.92] .31 MUL -10 [7.87] -20 X3 -25 -30 -35 -40 NOTES: -45 -55 X1 1. Optional input connectors SMA, K or output connectors -50 K, V or GPO type male. -60 -65 -70 X4 X2 2. Optional waveguide output available, REJECTION (dBc) -75 please contact MITEQ. -80 10.6 11.0 11.4 11.8 12.2 12.6 13.0 13.4 3. All dimensions shown in brackets [ ] are in millimeters. *(PIN = +10 dBm) INPUT FREQUENCY (GHz)

435 ACTIVE 3X FREQUENCY MULTIPLIER

MODEL: SYS3X2327

FEATURES • High fundamental rejection...... -50 dBc • Output power ...... +10 dBm • Packaging...... Hermetically sealed

ELECTRICAL SPECIFICATIONS

INPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. RF frequency range GHz 7.66 9 RF VSWR 50 ohm reference Ratio 2.5:1 RF power range dBm +3 V+ bias voltage @ 180 mA max. VDC 9 16 V- bias voltage @ 15 mA max. -9 -16

TRANSFER CHARACTERISTICS CONDITION UNITS MIN. TYP. MAX. Output power dBm +7 +10

Fundamental leakage Input dBc 60 40 M U

Second-harmonic leakage Input dBc 50 30 L T I Fourth-harmonic leakage Input dBc 50 20 P L I E R

OUTPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. P R

RF frequency range GHz 23 27 O D

RF VSWR 50 ohm reference Ratio 2.5:1 U C T S

NOTE: Test data supplied at 25°C; fundamental rejection, MAXIMUM RATINGS output power, second- and fourth-harmonic suppression. Specification temperature...... +25°C Operating temperature ...... -40 to +65°C OUTLINE DRAWING Storage temperature...... -65 to +95°C

0.62 [15.75] 0.38 MOUNTING SURFACE (SEE NOTE 1) ADD SUFFIX TO [9.65] MODEL NO. OPTIONS 0.13 [3.30] 0.13 [3.30] WG (WR42) WR42 output waveguide S Single positive supply 0.900 [22.86] 0.375 TYPE 'K' OR 2.9mm [9.53] FIELD REPLACEABLE 0.114 [2.90] 0.070 0.230 FEMALE 0.225 [5.72] [1.78] [5.84] CONNECTOR Output Power O 0.343 2X Fundamental [8.71] GND V+ 0.547 0.687 Fundamental [13.89] IN OUT [17.45] 4X Fundamental -V

TYPE 'SMA' FIELD HARMONICS 0.311* [7.90] REPLACEABLE X2Ø .100 [2.54] THRU MTG. HOLE 20 0.200* [5.08] FEMALE ) CONNECTOR 0.440 OPTIONAL GROUND TERMINAL [11.18] m B

4 0 d 1 ( /

8 0.52 [13.21] R 1 0.28 -20 / E

6 [7.11] 0 W :

O -40 d 0.13 [3.30] 0.13 [3.30] P e s i T v -60 U e OPTIONAL SPACER PLATE* P/N:140918 0.086* [2.18] P R T B

U -80 4 NOTES: 1. Unit’s mounting surface shall be attached to a heatsink capable of O 3 -

C dissipating the devices power consumption without exceeding the -100 operating temperature limits. 7600 7800 8000 8200 8400 8600 8800 9000 2. All dimensions shown in brackets [ ] are in millimeters. INPUT FREQUENCY (MHz)

100 Davids Drive, Hauppauge, NY 11788 • TEL: (631) 439-9220 • FAX: (631) 436-7430 • www.miteq.com 436 437 MULTIPLIER PRODUCTS 0.311* [7.90] akgn ...... Hermetically sealed ...... Packaging • +23dBm ...... Highoutputpower • -80dBc Highfundamentalrejection...... • FEATURES 0.200* [5.08] 0.225 [5.72] OE:1 Unit’s mounting surfaceshallbeattachedtoaheatsinkcapableof 1. NOTES: 0.114 [2.90] UPTPRMTR ODTO NT I.TP MAX. TYP. MIN. UNITS MAX. CONDITION TYP. MIN. MAX. UNITS TYP. MIN. CONDITION UNITS OUTPUT PARAMETERS CONDITION TRANSFER CHARACTERISTICS INPUT PARAMETERS FfeunyrneGz3. 34.8 2:1 -70 -60 33.3 +23 -80 GHz -80 +21 Ratio -16 16 dBm 50ohmreference 11.6 dBc dBc +15 -9 dBm 9 11.1 Input Input VDC GHz VDC max. @25mA max. @320mA RF VSWR RF frequencyrange Second-harmonic leakage Fundamental leakage Output power V- bias voltage V+ biasvoltage RF powerrange RF VSWR RF frequencyrange OE Test datasuppliedat25°C; NOTE: .Alldimensionsshown inbrackets[]aremillimeters. 2. OPTIONAL SPACERPLATE*P/N:140918 operating temperature limits. dissipating thedevicespowerconsumption withoutexceedingthe fundamental rejectionandoutputpower. [8.71] 0.343 TYPE 'SMA'FIELD REPLACEABLE CONNECTOR ULN DRAWING OUTLINE 0.13 [3.30] FEMALE [1.78] 0.070 ACTIVE 3XFREQUENCYMULTIPLIER (CONT.) 0.13 [3.30] [13.89] 0.547 [5.84] 0.230 [7.11] 0.52 [13.21] 0.28 IN [9.65] 0.62 [15.75] 0.38 0.900 [22.86] -V GND [11.18] 0.440 ELECTRICAL SPECIFICATIONS V+ OUT MODEL: SYS3X3334 0.086* [2.18] MOUNTING SURFACE(SEENOTE1) OPTIONAL GROUNDTERMINAL [9.53] 0.375 X2Ø .100[2.54]THRUMTG.HOLE 0.13 [3.30] 0.13 [3.30] [17.45] 0.687 CONNECTOR FEMALE FIELD REPLACEABLE TYPE 'K'OR2.9mm 0omrfrneRto2:1 Ratio 50 ohmreference trg eprtr...... -65 to +95°C Storage temperature...... -40to+65°C ...... Operating temperature +25°C Specification temperature...... RATINGS MAXIMUM Singlepositivesupply WR28outputwaveguide OPTIONS S WG MODEL NO. ADD SUFFIXTO

-100 OUTPUT POWER (dBc) -75 -50 -25 25 0 111. 11.15 11.1 11.1 10 121. 13 11.4 11.35 11.3 11.2 11.05 INPUT FREQUENCY (GHz) HARMONICS 11.25 3X Fundamental 2X Fundamental Fundamental 11.45 11.5 11.55 11.6 MULTIPLIER PRODUCTS 438 Fundamental 2X Fundamental 3X Fundamental 11850 HARMONICS INPUT FREQUENCY (MHz) 11750 11825 11875 11900 11925 11725 11775 11800 0

-25 -50 -75

-100 OUTPUT POWER (dBc) POWER OUTPUT ADD SUFFIX TO MODEL NO.S OPTION supply Single positive MAXIMUM RATINGS Specification temperature...... +25°C Operating temperature ...... -40 to +65°C Storage temperature...... -65 to +95°C 4X #4–40 UNC-2B COVER FLANGE 0.100 [2.54] 1.25 [31.75] CONFORMS TO WR28 0.80 4X .100 [2.54] DIA. THRU 1.050 [20.32] [26.67] ELECTRICAL SPECIFICATIONS MODEL: SYS3X3550WG MODEL: MOUNTING SURFACE (SEE NOTE 1) OPTIONAL GROUND TERMINAL 1.525 [38.735] 0.100 [2.54] 1.936 [49.174] ±.02 [0.51] 1.936 [49.174] ±.02 ±.02 0.38 [0.51] [9.65] ACTIVE 3X FREQUENCY MULTIPLIER (CONT.) MULTIPLIER FREQUENCY 3X ACTIVE OUTLINE DRAWING 0.43 [10.92] 2X .38 [9.65] FIELD 2X .62 [15.75] FEMALE 2X .45 [11.43] TYPE "SMA" CONNECTOR REPLACEABLE leakage at 1X and 2X output power. dissipating the devices power consumption without exceeding the operating temperature limits. 0.125 [3.175] 2. [ ] are in millimeters. All dimensions shown in brackets NOTE: data supplied at 25°C; Test Fundamental leakageSecond-harmonic leakageRF frequency rangeRF VSWR Input Input dBc dBc 50 ohm reference Ratio -65 GHz -90 35.4 -55 2:1 35.7 RF power rangeV+ bias voltage bias voltageV- Output power @ 300 mA max. @ 20 mA max. VDC VDC dBm +13 15 -15 dBm +14.5 RF frequency rangeRF VSWR 50 ohm reference Ratio GHz 11.8 2:1 11.9 0.62 [15.75] OUTPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. TRANSFER CHARACTERISTICS CONDITION UNITS MIN. TYP. MAX. INPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. NOTES: 1. be attached to a heatsink capable of mounting surface shall Unit’s •rejection...... High fundamental -90 dBc • Output power...... +14.5 dBm • Packaging ...... Hermetically sealed FEATURES 439 MULTIPLIER PRODUCTS 0.311* [7.90] 0.200* [5.08] akgn ...... Hermetically sealed ...... Packaging • +15dBm Outputpower...... • -60dBc Highfundamentalrejection...... • FEATURES 0.225 [5.72] OE:1 Unit’s mounting surfaceshallbeattachedtoaheatsinkcapableof 1. NOTES: 0.114 [2.90] OE Test datasuppliedat25°C; NOTE: UPTPRMTR ODTO NT I.TP MAX. TYP. MIN. UNITS CONDITION MAX. TYP. MIN. MAX. UNITS TYP. MIN. CONDITION OUTPUT PARAMETERS UNITS CONDITION TRANSFER CHARACTERISTICS INPUT PARAMETERS FfeunyrneGz3. 37.65 36.6 -50 +15 -55 GHz -60 -70 +12 -15 +13 15 dBm 12.5 dBc dBc dBc 2.1:1 -9 Input dBm 9 12.2 Input Input VDC GHz VDC max. @20mA Ratio max. @200mA 50ohmreference RF frequencyrange Fourth-harmonic leakage Second-harmonic leakage Fundamental leakage Output power V- bias voltage V+ biasvoltage RF powerrange RF VSWR RF frequencyrange FVW 0omrfrneRto2.1:1 Ratio 50ohmreference RF VSWR .Alldimensionsshown inbrackets[]aremillimeters. 2. OPTIONAL SPACERPLATE*P/N:140918 and second-harmonicleakage. operating temperature limits. dissipating thedevicespowerconsumption withoutexceedingthe [8.71] 0.343 TYPE 'SMA'FIELD REPLACEABLE CONNECTOR ULN DRAWING OUTLINE 0.13 [3.30] FEMALE [1.78] 0.070 ACTIVE 3XFREQUENCYMULTIPLIER (CONT.) 0.13 [3.30] [13.89] 0.547 [5.84] 0.230 [7.11] 0.52 [13.21] 0.28 IN [9.65] 0.62 [15.75] 0.38 0.900 [22.86] -V fundamental rejection,outputpower GND [11.18] 0.440 ELECTRICAL SPECIFICATIONS V+ OUT MODEL: SYS3X3637 0.086* [2.18] MOUNTING SURFACE(SEENOTE1) OPTIONAL GROUNDTERMINAL [9.53] 0.375 X2Ø .100[2.54]THRUMTG.HOLE 0.13 [3.30] 0.13 [3.30] [17.45] 0.687 CONNECTOR FEMALE FIELD REPLACEABLE TYPE 'K'OR2.9mm trg eprtr...... -65 to +95°C Storage temperature...... -40to+65°C ...... Operating temperature +25°C Specification temperature...... RATINGS MAXIMUM OUTPUT POWER Singlepositivesupply (dBm) WR28outputwaveguide OPTIONS S WG MODEL NO. ADD SUFFIXTO

-100

-10 -20 -30 -40 -50 -60 -70 -80 -90

20 10

0 221.012.35 12.30 12.2 22 241. 12.55 12.5 12.4 12.25 INPUT FREQUENCY (GHz) HARMONICS 4X Fundamental 3X Fundamental 2X Fundamental Fundamental 12.45 MULTIPLIER PRODUCTS 440 1X Fundamental 2X Fundamental 3X Fundamental 12.75 12.9 HARMONICS INPUT FREQUENCY (GHz) 12.55 12.7 12.8 12.85 12.5 12.6 12.65 0

20 10

-10 -20 -30 -40 -50 -60 -70 -80 -90 OUTPUT POWER (dBm) POWER OUTPUT -100 ADD SUFFIX TO MODEL NO.WG (WR28) S OPTIONS WR28 output waveguide supply Single positive MAXIMUM RATINGS Specification temperature...... +25°C Operating temperature ...... -40 to +65°C Storage temperature...... -65 to +95°C TYPE 'K' OR 2.9mm FIELD REPLACEABLE FEMALE CONNECTOR 0.687 [17.45] 0.13 [3.30] 0.13 [3.30] .100 [2.54] THRU MTG. HOLE X2Ø 0.375 [9.53] OPTIONAL GROUND TERMINAL MOUNTING SURFACE (SEE NOTE 1) 0.086* [2.18] MODEL: SYS3X3738 MODEL: OUT V+ ELECTRICAL SPECIFICATIONS 0.440 [11.18] GND fundamental rejection, output power -V 0.900 [22.86] 0.38 0.62 [15.75] [9.65] IN 0.28 0.52 [13.21] [7.11] 0.230 [5.84] 0.547 [13.89] 0.13 [3.30] ACTIVE 3X FREQUENCY MULTIPLIER (CONT.) MULTIPLIER FREQUENCY 3X ACTIVE 0.070 [1.78] FEMALE 0.13 [3.30] OUTLINE DRAWING CONNECTOR REPLACEABLE TYPE 'SMA' FIELD 0.343 [8.71] dissipating the devices power consumption without exceeding the operating temperature limits. and second-harmonic leakage. OPTIONAL SPACER PLATE* P/N:140918 2. [ ] are in millimeters. All dimensions shown in brackets Fundamental leakageSecond-harmonic leakageRF frequency rangeRF VSWR Input Input dBc dBc 50 ohm reference Ratio -75 GHz -70 37 -50 2.1:1 38 RF power rangeV+ bias voltage bias voltageV- Output power mA @ 200 max.mA @ 20 max. VDC VDC 9 dBm -9 dBm 16 +13 -16 +12 +16 RF frequency rangeRF VSWR 50 ohm reference Ratio GHz 12.5 2.1:1 12.9 OUTPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. TRANSFER CHARACTERISTICS CONDITION UNITS MIN. TYP. MAX. INPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. NOTE: data supplied at 25°C; Test 0.114 [2.90] NOTES: 1. attached to a heatsink capable of mounting surface shall be Unit’s 0.225 [5.72] 0.200* [5.08] FEATURES •rejection...... High fundamental -70 dBc • Output power...... +16 dBm • Packaging ...... Hermetically sealed 0.311* [7.90] 441 MULTIPLIER PRODUCTS 0.311* [7.90] akgn ...... Hermetically sealed ...... Packaging • +16dBm Outputpower...... • -70dBc Highfundamentalrejection...... • FEATURES 0.200* [5.08] OE:1 Unit’s mounting surfaceshallbeattachedtoaheatsinkcapableof 1. NOTES: 0.225 [5.72] 0.114 [2.90] UPTPRMTR ODTO NT I.TP MAX. TYP. MIN. UNITS MAX. CONDITION TYP. MIN. MAX. UNITS TYP. MIN. CONDITION UNITS OUTPUT PARAMETERS CONDITION TRANSFER CHARACTERISTICS INPUT PARAMETERS FfeunyrneGz3 42 2.5:1 -60 38 -60 +16 -70 GHz -70 +15 Ratio -16 16 dBm 50ohmreference 14 dBc dBc +12 2.5:1 -9 dBm 9 12.6 Input Input VDC GHz VDC max. @15mA Ratio max. @200mA 50ohmreference RF VSWR RF frequencyrange Second-harmonic leakage Fundamental leakage Output power V- bias voltage V+ biasvoltage RF powerrange RF VSWR RF frequencyrange OE Test datasuppliedat25°C;fundamentalrejection NOTE: .Alldimensionsshown inbrackets[]aremillimeters. 2. OPTIONAL SPACERPLATE*P/N:140918 operating temperature limits. dissipating thedevicespowerconsumption withoutexceedingthe and outputpower. [8.71] 0.343 TYPE 'SMA'FIELD REPLACEABLE CONNECTOR ULN DRAWING OUTLINE 0.13 [3.30] FEMALE [1.78] 0.070 ACTIVE 3XFREQUENCYMULTIPLIER (CONT.) 0.13 [3.30] [13.89] 0.547 [5.84] 0.230 [7.11] 0.52 [13.21] 0.28 IN [9.65] 0.62 [15.75] 0.38 0.900 [22.86] -V GND [11.18] 0.440 ELECTRICAL SPECIFICATIONS V+ OUT MODEL: SYS3X3842 0.086* [2.18] MOUNTING SURFACE(SEENOTE1) OPTIONAL GROUNDTERMINAL [9.53] 0.375 X2Ø .100[2.54]THRUMTG.HOLE 0.13 [3.30] 0.13 [3.30] [17.45] 0.687 CONNECTOR FEMALE FIELD REPLACEABLE TYPE 'K'OR2.9mm trg eprtr...... -65 to +95°C Storage temperature...... -40to+65°C ...... Operating temperature +25°C Specification temperature...... RATINGS MAXIMUM OUTPUT POWER Singlepositivesupply (dBc) WR28waveguideadaptor OPTIONS S WG MODEL NO. ADD SUFFIXTO -100 -75 -50 -25 25 0 251 13.25 13 12.5 27 351413.75 13.5 12.75 INPUT FREQUENCY (MHz) HARMONICS 3X Fundamental 2X Fundamental Fundamental MULTIPLIER PRODUCTS 442 Fundamental 2X Fundamental 3X Fundamental rejection (80 dBc) HARMONICS INPUT FREQUENCY (GHz) 13.9 14.15 14.2 13.8 13.85 13.95 14 14.114.05 0

-25 -50 -75

-100 OUTPUT POWER (dBm) POWER OUTPUT ADD SUFFIX TO MODEL NO.WG (WR22) SVH OPTIONS WR22 output waveguide supply Single positive high fundamental Very MAXIMUM RATINGS Specification temperature...... +25°C Operating temperature ...... -40 to +65°C Storage temperature...... -65 to +95°C TYPE 'K' OR 2.9mm FIELD REPLACEABLE FEMALE CONNECTOR 0.687 [17.45] 0.13 [3.30] 0.13 [3.30] .100 [2.54] THRU MTG. HOLE X2Ø 0.375 [9.53] OPTIONAL GROUND TERMINAL MOUNTING SURFACE (SEE NOTE 1) 0.086* [2.18] MODEL: SYS3X1442 MODEL: OUT V+ ELECTRICAL SPECIFICATIONS 0.440 [11.18] fundamental rejection, GND -V 0.900 [22.86] 0.38 0.62 [15.75] [9.65] IN 0.28 0.52 [13.21] [7.11] 0.230 [5.84] 0.547 [13.89] 0.13 [3.30] ACTIVE 3X FREQUENCY MULTIPLIER (CONT.) MULTIPLIER FREQUENCY 3X ACTIVE 0.070 [1.78] FEMALE 0.13 [3.30] OUTLINE DRAWING CONNECTOR REPLACEABLE TYPE 'SMA' FIELD 0.343 [8.71] dissipating the devices power consumption without exceeding the operating temperature limits. output power and second-harmonic leakage. OPTIONAL SPACER PLATE* P/N:140918 2. [ ] are in millimeters. All dimensions shown in brackets Fundamental leakageSecond-harmonic leakageRF frequency rangeRF VSWR Input Input dBc dBc 50 ohm reference Ratio -80 GHz -80 -60 -60 2.75:1 42 RF power rangeV+ bias voltage bias voltageV- Output power @ 180 mA max. @ 15 mA max. VDC VDC 9 dBm -9 dBm 16 +12 -16 +14 +16 RF frequency rangeRF VSWR 50 ohm reference Ratio GHz 2.5:1 14 OUTPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. TRANSFER CHARACTERISTICS CONDITION UNITS MIN. TYP. MAX. INPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. NOTE: data supplied at 25°C; Test NOTES: 1. be attached to a heatsink capable of mounting surface shall Unit’s 0.114 [2.90] 0.225 [5.72] 0.200* [5.08] FEATURES •rejection...... High fundamental -80 dBc • Output power...... +16 dBm • Packaging ...... Hermetically sealed 0.311* [7.90] 443 MULTIPLIER PRODUCTS 0.311* [7.90] akgn ...... Hermetically sealed ...... Packaging • +16dBm Outputpower...... • -60dBc Highfundamentalrejection...... • FEATURES 0.200* [5.08] OE:1 Unit’s mounting surfaceshallbeattachedtoaheatsinkcapableof 1. NOTES: 0.225 [5.72] 0.114 [2.90] UPTPRMTR ODTO NT I.TP MAX. TYP. MIN. UNITS CONDITION MAX. TYP. MIN. MAX. UNITS TYP. MIN. CONDITION OUTPUT PARAMETERS UNITS CONDITION TRANSFER CHARACTERISTICS INPUT PARAMETERS FfeunyrneGz4 46 2.75:1 41 -45 +16 GHz -60 Ratio +13 -16 50ohmreference +12 16 dBm 11.5 dBc dBc dBc 2.5:1 -9 Input dBm 9 10.25 Input Input VDC GHz VDC max. @15mA Ratio max. @180mA 50ohmreference RF VSWR RF frequencyrange Third-harmonic leakage Second-harmonic leakage Fundamental leakage Output power V- bias voltage V+ biasvoltage RF powerrange RF VSWR RF frequencyrange OE Test datasuppliedat25°C; NOTE: .Alldimensionsshown inbrackets[]aremillimeters. 2. OPTIONAL SPACERPLATE*P/N:140918 operating temperature limits. dissipating thedevicespowerconsumption withoutexceedingthe fundamental rejectionandoutputpower. [8.71] 0.343 TYPE 'SMA'FIELD REPLACEABLE CONNECTOR ULN DRAWING OUTLINE 0.13 [3.30] FEMALE [1.78] 0.070 0.13 [3.30] [13.89] 0.547 [5.84] 0.230 ACTIVE 4XFREQUENCYMULTIPLIER [7.11] 0.52 [13.21] 0.28 IN [9.65] 0.62 [15.75] 0.38 0.900 [22.86] -V GND [11.18] 0.440 ELECTRICAL SPECIFICATIONS V+ OUT MODEL: SYS4X1146 0.086* [2.18] MOUNTING SURFACE(SEENOTE1) OPTIONAL GROUNDTERMINAL [9.53] 0.375 X2Ø .100[2.54]THRUMTG.HOLE 0.13 [3.30] 0.13 [3.30] [17.45] 0.687 CONNECTOR FEMALE FIELD REPLACEABLE TYPE 'K'OR2.9mm trg eprtr...... -65 to +95°C Storage temperature...... -40to+65°C ...... Operating temperature +25°C Specification temperature...... RATINGS MAXIMUM Singlepositivesupply WR42 outputwaveguide OPTIONS S WG (WR42) MODEL NO. ADD SUFFIXTO MULTIPLIER PRODUCTS 444 2.150 Fundamental 3X Fundamental 4X Fundamental 5X Fundamental 6X Fundamental 7X Fundamental HARMONICS INPUT FREQUENCY (GHz) 2.05 2.125 2.175 2.2 0 2.02 2.075 2.1

-25 -50 -75

-100 DESIRED (dBm) and HARMONICS (dBc) HARMONICS and (dBm) DESIRED ADD SUFFIX TO MODEL NO.WG (WR42) S OPTIONS WR42 output waveguide supply Single positive MAXIMUM RATINGS Specification temperature...... +25°C Operating temperature ...... 0 to +40°C Storage temperature...... -65 to +125°C TYPE SMA MALE CONNECTOR 0.275 [6.985] 0.162 [4.115] 0.125 [3.175] 0.800 [20.32] 6X #2–56 X 0.100 [2.54] DP. MOUNTING HOLES 0.550 [13.97] 0.500 [12.70] IN ELECTRICAL SPECIFICATIONS MODEL: SYS5J100100 MODEL: 0.776 [19.71] 1.96 [49.78] .04 [1.02] ACTIVE 5X FREQUENCY MULTIPLIER FREQUENCY 5X ACTIVE 2.688 [68.275] 3.11 [78.99] 0.033 [0.838] 0.418 [10.617] ± OUTLINE DRAWING OUT +12 VDC 0.198 [5.029] 0.195 [4.953] fundamental and harmonic leakage and output power. fundamental and harmonic leakage and dissipating the devices power consumption without exceeding the operating temperature limits. GND 2. [ ] are in millimeters. All dimensions shown in brackets 0.480 FEMALE [12.192] TYPE "SMA" 0.240 [6.096] CONNECTOR NOTE: data supplied at 25°C; Test Harmonic leakageSpuriousRF frequency rangeRF VSWR Input 980–1020 MHz dBc dBc 50 ohm reference Ratio GHz -70 -80 -50 2:1 -60 10 RF power rangeV+ bias voltageOutput powerFundamental leakage mA @ 250 typ. VDC Input +15 dBm dBc +10 dBm +10 -70 -50 RF frequency rangeRF VSWR 50 ohm reference Ratio GHz 2.5:1 2 ±.04 [1.02] OUTPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. TRANSFER CHARACTERISTICS CONDITION UNITS MIN. TYP. MAX. INPUT PARAMETERS CONDITION UNITS MIN. TYP. MAX. 0.286 [7.264] MAX. 0.472 [11.988] NOTES: 1. be attached to a heatsink capable of mounting surface shall Unit’s FEATURES •rejection...... High fundamental -70 dBc • Output power...... +10 dBm • Packaging ...... Hermetically sealed 445 MULTIPLIER PRODUCTS FEATURES option aswell. series) arealsoavailableasindividual“drop-in”components.IntermediateoutputsatX5andX10 asan nally tomaketheuniteasilymodifiedforcustomfrequencies. These microstripmultipliermodules(“FEM”and“FOM” VHF stabilizedorvoltage-tunedinputsource.Industrystandardsizeamplifierandmultipliermodulesareused inter- This integrated3stage,(X20)activemultipliersubsystemissuitableforreceiverLOgenerationusingareference -55dBm/MHz ...... Noiseoutput • +5dBm ...... Poweroutput • -55dBc Spurious(octaveBW)...... • 10percent ...... Input/outputBW • 0.15/3GHz ...... Input/outputfrequency • UPTPRMTR ODTO NT I.TP MAX. TYP. MIN. UNITS CONDITION MAX. TYP. OUTPUT PARAMETERS MAX. MIN. TYP. UNITS MIN. CONDITION UNITS CONDITION TRANSFER CHARACTERISTICS INPUT PARAMETERS FVW ai .: 2:1 +5 1.7:1 +3 3.15 dBm Ratio 55 2.85 GHz dBm/MHz -55 X20 10 -10 0.02 1.5:1 +13 -5 170 -55 dBc 158 Ratio -50 dB/Deg. Ratio +10 150 -55 3GHz @+5 output dBc dB @+25°C 142 mA Noise power(not includingsource) -50 dBm RF power RF VSWR MHz 150MHz 150MHz dBc RF frequencyrange @+15volts Output power, temperaturedependence 150MHz Spurious nonharmonicsuppression by outputpowerchange Input powerchangedivided (X20) Input tooutputpowersensitivity RF suppression(3GHzreference) Second harmonicofoutput (X19) Adjacent harmonicsuppression Conversion loss DC power RF VSWR RF powerrange RF frequencyrange 0.15 TO3GHz,(X20)MULTIPLIER SUBSYSTEM X1 5 H B 5 -55 -50 dBc 150MHz (X21) MODEL: SYS20M028032 ELECTRICAL SPECIFICATIONS MULTIPLIER PRODUCTS 446 -40°C +70°C +25°C Filter Filter Filter X 2 X 2 OUTPUT VSWR FREQUENCY (GHz) FREQUENCY (GHz) X 5 OVER TEMPERATURE SWEPT OUTPUT POWER SWEPT OUTPUT 2.8 2.85 2.9 2.95 3 3.05 3.1 3.15 3.2 3.25 2.8 2.85 2.9 2.95 3 3.05 3.1 3.15 3.2 3.25 5 4 3 2 1 0

3.0:1 2.5:1 2.0:1 1.5:1 1.0:1

2.75:1 2.25:1 1.75:1 1.25:1 POWER (dBm) POWER

(RATIO) VSWR TYPICAL TESTTYPICAL DATA RF OUTPUT +V .078[1.98] FINISH: NICKEL 158 160 4.23.6 (TYP. 4 PLACES) SYS20M028032 4.75[120.65] MOUNTING HOLE 3.709[94.21] .101 [2.56] DIA. THRU INPUT VSWR 2.4 (VBW=100 kHz) FREQUENCY (MHz) FREQUENCY (GHz) .34[8.56] MIDBAND SPECTRUM OUTLINE DRAWING BLOCK DIAGRAM 0 0.6 1.2 1.8 3 5.44.86 .61[15.52] 140 143 145 148 150 153 163155 1.63[41.40] 0

NOTE: Test data supplied at 25°C; Conversion loss, LO-RF isolation. data supplied at 25°C; Conversion Test NOTE: Specification temperature...... +25°C Operating temperature ...... -54 to +85°C Storage temperature ...... -65 to +125°C MAXIMUM RATINGS 10

-10 -20 -30 -40 -50 -60 -70 .43[10.97] RF INPUT

.60[15.24] 5.0:1 4.5:1 4.0:1 3.5:1 3.0:1 2.5:1 2.0:1 1.5:1 1.0:1

POWER (dBm) POWER VSWR (RATIO) VSWR All dimensions shown in brackets [ ] are in millimeters. NOTE: .38 [9.52](TYP)

447 MULTIPLIER PRODUCTS FEATURES tion, aninputlownoisepoweramplifierisprovidedtoallowseamlessintegrationwitha+10dBminputsource. spectrum iseasilyfiltered,duetothelargecombspacing(highinputfrequencyandmultiplicationorders). Inaddi- This unitissuitableforhigh-frequencyLOgenerationusingalowerfrequencyphasestablereference. The output Hermeticallysealed Packaging...... • Integratedinputpoweramplifier • Highmultiplicationratios • 0.5to1.5GHz ...... RFinput • 2to18GHz RFoutput...... • UPTPRMTR ODTO NT I.TP MAX. TYP. MIN. UNITS CONDITION MAX. TYP. MAX. MIN. TYP. UNITS MIN. CONDITION UNITS OUTPUT PARAMETERS CONDITION TRANSFER CHARACTERISTICS INPUT PARAMETERS FfeunyrneGz218 2:1 2 GHz Ratio 20 1.5 17 2:1 +13 0.5 dB +7 GHz Ratio 1.5GHzinput dBm RF VSWR RF frequencyrange (X2) Conversion loss RF VSWR RF powerrange RF frequencyrange 2 TO18GHzBIPOLAR/SRD/MESFETCOMBGENERATOR X2 B3 36 27 21 33 24 18 dB dB dB (X12) (X9) (X4) MODEL: EOM0218HW4 ELECTRICAL SPECIFICATIONS MULTIPLIER PRODUCTS 448 18 OUTPUT SRD RETURN LOSS FREQUENCY (GHz) RF INPUT BIAS RF 2 5.2 8.4 11.6 14.8 0.8 0.9 1 1.1 1.2 1.3

4 6 8 10 10 12 14 16

) B d ( S S O L N R U T E R .38 [9.65] .93 [23.62] .200 [85.08] .75 [19.05] CONNECTION .09 [2.29] TYPE "SMA" FIELD REPLACEABLE FEMALE (TYP. 2 PLACES) 5000 1 2.18 [55.37] 2.00 [50.80] .15 [3.81] TYP. IN OUT GND GND +DC THREAD FOR .086-56UNC-2B X 1.5 LENGTH LOCKING HELCAL COIL INSERT PER MS33537 (TYP. 4 PLACES) EOM0218HW4 TYPICALEOM0218HW4 TEST DATA = 13 dBm) = 1500 MHz) (+13 dBm) INPUT IN IN (P (F .38 [9.65] OUTPUT FREQUENCY (MHz) .09 [2.29] .680 [17.27] OUTLINE DRAWING BLOCK DIAGRAM .485 [12.319] 1.185 [30.099] .465 [11.811] OUTPUT POWER VS. FREQUENCY WITH 1500 MHz VS. FREQUENCY OUTPUT POWER .05 [1.27] TYP. 0 2500 5000 7500 10000 12500 17500

.200 [5.08] 0

.25 [6.35] -10 -20 -30 -40 -50 -60 -70 -80

) m B d ( R E W O P T U P T U O NOTE: Test data supplied at 25°C; Conversion loss, LO-RF isolation. data supplied at 25°C; Conversion Test NOTE: MAXIMUM RATINGS Specification temperature...... +25°C Operating temperature ...... -54 to +85°C Storage temperature ...... -65 to +125°C NOTE: All dimensions shown in brackets [ ] are in millimeters. NOTE: ACTIVE MULITPLIER ASSEMBLIES

MAX4M050055-14P 5 TO 5.5 GHz, MID OUTPUT LEVEL X 4 ACTIVE MULTIPLIER ELECTRICAL SPECIFICATIONS ASSEMBLIES Input frequency 1.25 – 1.375 GHz minimum OPTIONS Input power +10 dBm minimum • Input Power +5 to +20 dBm Input VSWR 2:1 typical Output frequency 5 – 5.5 GHz minimum Output power +14 dBm minimum Output power flatness (at +25°C) ±1.5 dB maximum Output spurious rejection -60 dBc typical Output harmonic rejection -15 dBc typical Rejection of input harmonics -50 dBc typical FUNCTIONAL BLOCK DIAGRAM Output VSWR 2:1 typical For units below 26 GHz DC power +15 VDC, 250 mA SWEPT OUTPUT POWER (with +10 dBm input) IN X 4 OUT 19 ) m B d (

R 18 E W O P

T 17 U P T U O 16

5 5.1 5.2 5.3 5.4 5.5 OUTPUT FREQUENCY (GHz)

TIPLIER PRODUCTS MAX4M062071 MAX4M400480

MUL 6.2 TO 7.1 GHz, MID OUTPUT LEVEL 40 TO 48 GHz, MID OUTPUT LEVEL ELECTRICAL SPECIFICATIONS ELECTRICAL SPECIFICATIONS Input frequency 1.55 – 1.78 GHz minimum Input frequency 10 – 12 GHz minimum Input power +10 dBm typical Input power +10 dBm minimum Input VSWR 2:1 typical Output frequency 40 – 48 GHz minimum Output frequency 6.2 – 7.1 GHz minimum Output power +8 dBm minimum Output power +10 dBm minimum Output power flatness (at +25°C) ±2 dB maximum Output power flatness (at +25°C) ±2 dB maximum Output spurious rejection -60 dBc typical Output spurious rejection -65 dBc typical Rejection of input harmonics -18 dBc typical Output harmonic rejection -15 dBc typical DC power +15 VDC, 200 mA Rejection of input harmonics -65 dBc typical Output VSWR 1.5:1 typical DC power +15 VDC, 250 mA SWEPT OUTPUT POWER SWEPT OUTPUT POWER (with +10 dBm input) (with +10 dBm input) 15 19 ) ) m m B

B 13 d d (

(

R 18 R E E W W 11 O O P P T 17 T U U P P T T 9 U U O 16 O

6.2 6.4 6.6 6.8 7.0 7.2 40 41.6 43.2 44.8 46.4 48 OUTPUT FREQUENCY (GHz) OUTPUT FREQUENCY (GHz)

449 ACTIVE MULTIPLIER ASSEMBLIES (CONT.)

MAX4M127134 12.71 TO 13.28 GHz, MID OUTPUT LEVEL ELECTRICAL SPECIFICATIONS Input frequency 3.1775 – 3.32 GHz minimum Input power +12 dBm typical Input VSWR 2.5:1 typical Output frequency 12.71 – 13.28 GHz minimum Output power +13 dBm typical Output power flatness (at +25°C) ±1 dB maximum Output spurious rejection -65 dBc typical Output harmonic rejection -15 dBc typical Rejection of input harmonics -65 dBc typical Output VSWR 1.5:1 typical DC power +5 VDC, 110 mA* * -2.5 V required.

SWEPT OUTPUT POWER (with +12 dBm input)

15.5 MUL ) m B TIPLIER PRODUCTS d (

R 14.5 E W O P

T 13.5 U P T U O 12.5

12.71 12.824 12.938 13.052 13.166 13.28 OUTPUT FREQUENCY (GHz)

450 PASSIVE MULTIPLIERS – OUTLINE DRAWINGS

GENERAL NOTES

1. All dimensions shown in brackets [ ] are in millimeters. Tolerance as follows: .xx = ±0.01 [.xx = ±0.25] .xxx = ±0.005 [.xxx = ±0.13]

2. Optional SMA, K or V type male. SMA type only, on multipliers below 26 GHz.

MX2A MX2B

1.25 [31.75] SMA FIELD REPLACEABLE FEMALE (.012 [.30] DIA. PIN ON .88 [22.35] HOUSING) (TYP. 2 PLACES) .17 [4.32] .113 [2.87]

.101 [2.56] .226 .375 [9.53] DIA. THRU RF INPUT [5.74] (2 MOUNTING HOLES) 2-56 THRU .075 [1.91] .28 [7.11] (2 PLACES .38 [9.65] TYP. MARKED A) .75 SQ. [19.05]

TIPLIER PRODUCTS .48 .38 [9.65] [12.19] .055 [1.40] .80 [20.32] .95 [24.13] MUL RF OUTPUT .17 [4.32] .075 [1.91] SMA FIELD A B 1.10 [27.94] REPLACEABLE FEMALE .64 [16.26] (TYP. 2 PLACES) B A

.089 [2.26] DIA. .235 [5.97] THRU, (2 PLACES MARKED B) .28 [7.11]

451 PASSIVE MULTIPLIERS – OUTLINE DRAWINGS (CONT.)

MX2C MX2D

SMA FIELD REPLACEABLE FEMALE .43 [10.92] .29 [7.37] (.012 [.30] DIA. PIN ON HOUSING) .16 [4.06] .18 [4.57] (TYP. 2 PLACES) .38 .11 [2.79] [9.65] INPUT B .35 [8.89] .59 [15.0] .698 [17.73] A .38 [9.65] TYP. 2 PLACES 2-56 THRU .273 [6.93] SMA FEMALE (2 PLACES .75 SQ. [19.05] 0-80 HARDWARE THRU (TYP. BOTH ENDS) MARKED A) .070 [1.78] DIA. HOLES

.055 [1.40]

.38 TYP. [9.65] .428 [10.87] .158 [4.0] .18 [4.57] A B .075 [1.91] .64 [16.26] B A .36 [9.14] .48 [12.19] .57 [14.48] OUTPUT RF INPUT .089 [2.26] DIA. .007 [.178] RF OUTPUT .235 [5.97] .175 [4.45] THRU, (2 PLACES .015 [.38] DIA. PIN MUL .273 [6.93] (TYP. BOTH ENDS) MARKED B) .28 [7.11] .585 [14.85] TIPLIER PRODUCTS

OUTLINE DIM A DIM B NOTE:Doubler may be readily used as is, or as a drop-in by DASH NO. removing the SMA connectors and mounting hardware as -1 .226 [5.74] .121 [3.07] shown.

MX2E MXF

.666 [16.92]

K STYLE FEMALE, 26 TO 40 GHz OUTPUT .06 [1.52] .15 .131 MOUNTING [3.81] .418 [10.63] INPUT [3.33] SURFACE

RF OUTPUT .368 [9.35] .37 .613 [9.40] .85 [15.57] SMA FIELD REPLACEABLE [.21.59] FEMALE, 13 TO 20 GHz INPUT

.200 x2 .38 X2 Ø .079 [2.01] [5.08] .294 [7.47] [9.65] .43 MOUNTING HOLES [10.92] .31 [7.87]

NOTE:Optional waveguide output available, please contact MITEQ.

452 ACTIVE MULTIPLIERS – OUTLINE DRAWINGS

GENERAL NOTES

1. All dimensions shown in brackets [ ] are in millimeters. Tolerance as follows: .xx = ±0.01 [.xx = ±0.25] .xxx = ±0.005 [.xxx = ±0.13]

2. Optional SMA, K or V type male. SMA type only, on multipliers below 26 GHz.

MAX2A MAX2B

1.800 [45.72] .250 [6.35] 1.300 [33.02] +15 V RF OUTPUT 1.100 [27.94] GROUND .900 [22.86] .070 [1.78] .980 [24.89] .840 [21.34] .070 [1.78] RF INPUT .700 [17.78] GROUND .101 [2.57] DIA. THRU MOUNTING RF INPUT 1.050 [26.67] HOLES (4 PLACES) 1.250 [31.75] +15 V RF .070 [1.78] 1.323 [33.60] OUTPUT 1.463 [37.16]

.360 [9.14] .420 [10.67] .144 [3.66]

TIPLIER PRODUCTS .490 [12.45] .840 [21.34] MUL

.210 [5.33] .360 [9.14] .110 [2.79]

MAX2A2

2.24 [56.90] SMA TYPE .08 [2.03] 2.085 [52.959] FEMALE .36 [9.14] RF OUTPUT .14 [3.56] .08 [2.03] .49 [12.45] .830 .98 SMA TYPE [21.08][24.89] FEMALE RF INPUT GROUND 1.60 [40.64] +5 V .11 [2.79] 1.87 [47.50]

453 ACTIVE MULTIPLIERS – OUTLINE DRAWINGS (CONT.)

MAX2C MAX2C2

1.26 [32.00] 1.07 [27.18] .91 [23.11] .73 [18.54] .68 [17.27] RF OUTPUT .49 [12.45] RF OUTPUT .070 [1.78] DIA. GROUND .070 [1.78] DIA. GROUND DC POWER DC POWER MOUNTING HOLES .43 [10.92] MOUNTING HOLES .43 [10.92] (TYP. 2 PLACES) (TYP. 2 PLACES) .16 .11 [2.79] .16 [4.06] .11 [2.79] [4.06] .28 [7.11] .070 [1.78] .28 [7.11] .070 [1.78] .70 .480 .480 .500 [12.70] .70 [17.78] [12.19] [17.78] [12.19] .500 [12.70]

.27 [6.86] .100 [25.4] DIA. .27 [6.86] .100 [25.4] DIA. 131218 REF .210 [5.33] 131218 REF .210 [5.33] MOUNTING HOLES RF INPUT MOUNTING HOLES RF INPUT (TYP. 4 PLACES) .654 (TYP. 4 PLACES) .835 [21.21] [16.61] 121623 -6 REF 121623-5 REF. 2.38 [60.45] 2.19 [55.63]

.11 [2.79] TYPE SMA FIELD .11 [2.79] TYPE SMA FIELD .19 [4.83] REPLACEABLE .19 [4.83] REPLACEABLE FEMALE CONNECTOR .32 [8.13] .32 [8.13] FEMALE CONNECTOR (TYP. BOTH ENDS) (TYP. BOTH ENDS) .64 [16.26] .64 [16.26]

.20 [5.08] MUL .20 [5.08] .31 [7.87] MOUNTING SURFACE .31 [7.87] MOUNTING SURFACE TIPLIER PRODUCTS

MAX2D MAX2E

.375 [9.53] TYP.

4.862 [123.49] 4.285 [108.84] .165 [4.19] 4.165 [105.79] .500 [12.70] 3.165 [80.39] 3.510 [89.15] .525 [13.34] 1.580 3.188 [80.98] .125 [3.18] [40.13] +5 V +5 VDC RF POWER INPUT 1.600 [40.64] .550 [13.97]

RF INPUT 0.093 [2.36] THRU, C'BORE 0.190 [4.83] X .125 [3.18] .080 [2.03] DEEP MOUNTING HOLES (6 PLACES) .500 [12.70] 1.255 [31.87] #2-56 X .15 [3.81] DEEP 4.042 [102.67] MOUNTING HOLES (4 PLACES) RF .600 [15.24] MAIN OUTPUT .375 [9.53] RF OUTPUT TYP. .267 [6.78] RF .321 [8.15] SMA FEMALE COUPLED PORT CONNECTOR .162 [4.11] TYP. (2 PLACES) .400 [10.16] TYP. 2.100 [53.33] 1.700 .800 [20.32] [43.17] 1.200 [30.48] .800 [20.32]

.100 [2.54] .165 [4.19] .270 [6.86]

454

ACTIVEACTIVE MULTIPLIERS MULTIPLIERS –– OUTLINEOUTLINE DRAWINGSDRAWINGS (CONT.)(CONT.)

MAX2G MAX2H

2.0 .58 [50.80] .21 [5.33] .18 [4.57] .94 [23.88] RF [14.73] OUTPUT RF INPUT +VDC .38 [9.65] (SEE NOTE 2) .47 [11.94] [SEE NOTE 2] RF OUTPUT RF INPUT

.74 [18.80] .613 [15.57]

1.56 [39.62] +VDC

.85 [21.59] .06 [1.52] .06 [1.52] 1.23 [31.24] .106 [2.69] 1.53 [38.86] 1.046 [26.57] .38 [9.65] 1.438 [36.53] .38 [9.65] .15 [3.81] .31 [7.87] .94 GROUND .079 [2.01] DIA. [23.88] (6 MOUNTING HOLES) .14 [3.56] (4 PLACES) .37 [9.40]

.96 [24.38]

.85 [21.59] CONFORMS TO WR28 COVER .20 [5.08] FLANGE .35 [8.89] (MAX.) .25 [6.35]

TIPLIER PRODUCTS MAX2J MAX2K MUL

1.95 [49.53]

.33 [8.38] .66 [16.76]

.15 .131 [3.33] +VDC .08 [2.03] 1.80 [45.72] .08 [2.03] [3.81] .90 [22.86] (6 PLACES) .06 MOUNTING +VDC [1.52] SURFACE INPUT 1.10 [27.94] .363 1.25 RF OUTPUT [9.35] [31.75] OUTPUT .613 .85 [15.57] [21.59]

.07 [1.78] .38 [9.65] (2 PLACES) .15 [3.81] GROUND

.200 .09 [2.29] [5.08] .95 [24.13] X2 .38 .43 X2 Ø.079 [2.01] [9.65] MOUNTING HOLES .33 [8.38] [10.92] .31 .16 [4.06] [7.87]

.23 [5.84] .09 [2.29] .53 [13.46] .94 [23.88] NOTE:Optional waveguide output available, please contact MITEQ.

455 ACTIVE MULTIPLIERS – OUTLINE DRAWINGS (CONT.)

MAX2L MAX2M

X2 .076 [1.93] HOLE THRU .15 .210 .18 .576 [3.81] [5.33] [4.57] [14.63] +VDC +VDC .06 .470 [1.52] MOUNTING [11.94] INPUT SURFACE .52 INPUT RF [13.21] OUTPUT .368 OUTPUT [9.35] .613 .74 .613 .85 [15.57] [18.21] [15.57] [21.59] .37 [9.40]

.06 -VDC .106 [1.52] .200 [5.08] GND .200 [2.69] [5.08] .30 .38 .51 .38 [7.62] [9.65] [12.95] .93 [9.65] .33 [23.62] [8.38] GND X4 .076 [23.62] MOUNTING HOLE .12 [3.05] MOUNTING SURFACE MUL TIPLIER PRODUCTS NOTE:Optional waveguide output available, please contact MITEQ.

MAX2N MAX3A

.80 [20.32]

.38 .646 [16.41] [9.65] TYP. .18 .470 +VDC [4.57] [11.94] .48 [12.19] .13 .176 .58 [3.30] [4.47] RF [14.73] INPUT OUTPUT 3.19 [81.03] +5 VDC .369 [9.37] .50 [12.70] .776 [19.71]

.613 .74 .125 [3.18] RF OUTPUT [15.57] [18.80]

.200 .550 [13.97] .062 [5.08] [1.57] .076 .31 .102 X4 [1.93] [7.87] RF INPUT .38 [25.91] -VDC [9.65] .38 [9.65] TYP. 3.51 [89.15] 2-56 X .24 [6.10] DEEP TYPE SMA FEMALE MOUNTING HOLES FIELD REPLACEABLE (TYP. 4 PLACES) CONNECTOR (TYP. 2 PLACES)

.12 [3.05]

.40 [10.16]

456 ACTIVE MULTIPLIERS – OUTLINE DRAWINGS (CONT.)

MAX4A MAX4B

REF: HOUSING DC POWER MITEQ P/N 118820 .38 [9.65] 3.90 [99.06]

.40 [10.16] .80 [20.32] GROUND

TYPE SMA FEMALE CONNECTOR (TYP. BOTH ENDS) .156 [3.96] .18 [4.57] .375 4.595 [116.71] [9.53] TYP. 4.285 [108.84] .50 [12.70]

RF INPUT RF OUTPUT RF INPUT 4.900 [124.46] SPACER PLATE AFS4 AMPLIFIER +5 V MITEQ P/N:125387 2.231 [56.67] -2.5 V .480 .500 [12.70] .776 [19.71] [12.19]

.550 [13.97] .550 [13.97]

.125 [3.18] .776 [19.71] .159 .125 [3.18] RF OUTPUT SMA FEMALE [4.04] CONNECTORS (TYP. 2 PLACES) .500 [12.7] 2.982 [75.74] #2-56 X .16 [4.06] DEEP MOUNTING HOLES (6 PLACES) 3.212 [81.58] 1.125 [28.58] .400 [10.16] TYP. 2-56 TAP X .20 [5.08] DEEP OPTIONAL MOUNTING MOUNTING HOLES (CLEARANCE FOR 0-80 SCREW) (TYP. 4 PLACES) .167 [4.24] TYP. .469 [11.91] TIPLIER PRODUCTS MAX4C MAX4D MUL

1.234 [31.34]

.313 [7.95] 4.900 [124.46] 4.617 [117.27] 4.367 [110.92] 4.165 [105.79] 4.285 [108.84] .500 [12.70] 3.165 [80.39] 4.595 [116.71] +5 V .525 [13.34] 1.580 .125 [3.18] [40.13] -2.5 V 2-56 UNC X .16 [4.06] DEEP 2.231 [56.67] MOUNTING HOLES (6 PLACES) .776 [19.71] +5 V +2.5 V .500 [12.70] 1.600 [40.64] RF COUPLED .125 [3.18] PORT 0.093 [2.36] THRU, C'BORE RF INPUT .550 [13.97] +5 V 0.190 [4.83] X .080 [2.03] DEEP RF RF RF INPUT MOUNTING HOLES (6 PLACES) MAIN 3.445 [87.50] MAIN OUTPUT 1.125 [28.58] OUTPUT .600 [15.24] 4.328 [109.93] .268 [6.81] 4.900 [124.46] .500 [12.70] 1.200 [30.48] .167 [4.24] .800 [20.32]

.100 [2.54] 1.300 [33.02] .270 [6.86] .925 [23.50] .400 [10.16]

457 ACTIVE MULTIPLIERS – OUTLINE DRAWINGS (CONT.)

MAX4E MAX5A

4.150 [105.41] RF COUPLED RF INPUT +5 V AFS SERIES 3.11 [78.99] PORT 4 STAGE AMPLIFIER 1.78 [45.21] TYPE SMA FEMALE 1.600 [40.64] RF MAIN CONNECTORS .80 [20.32] OUTPUT (TYP. 2 PLACES) -2.5 V .500 [12.70] 1.580 [40.13] +5 V .38 [9.65] (TYP.) 3.165 [80.39] 0.093 [2.36] THRU C'BORE 4.165 [105.79] 0.190 [4.83] X .080 [2.03] DEEP MOUNTING HOLES (6 PLACES) 4.900 [124.46] 4.617 [117.27] .49 [12.45] 4.367 [110.92] .600 [15.24]

.18 [4.57] .16 [4.06] .350 .125 [8.89] .480 [3.18] .525 [12.19] 2.688 [68.28] .275 [6.99] [13.34] .240 [6.10]

.550 [13.97]

.198 [5.03] .500 [12.70] .776 [19.71] .267 [6.78] 2-56 TAPPED MOUNTING HOLES (TYP. 4 PLACES) MUL 1.993 [50.62] .087 [2.21] DIA. MOUNTING HOLES 1.200 (TYP. 2 PLACES) TIPLIER PRODUCTS [30.48] .800 [20.32]

.100 [2.54]

120373 149228

1.500 [38.10] .875 [22.225] 3.11 [78.99] 0.286 [7.264] 0.195 .068 [1.727] .625 ±.04 [1.02] 0.033 [0.838] 0.162 [4.115] [15.875] [4.953] 0.472 [11.988] MAX. .590 [14.986] 0.418 [10.617] ± .04 [1.02] GND TYPE "SMA" TYPE SMA FEMALE +12 VDC MALE .089 [2.489] DIA. THRU CONNECTOR CONNECTOR MOUNTING HOLES OUT IN 0.800 [20.32] (4 PLACES)

.110 [2.794] 6X #2–56 X 0.100 [2.54] .210 [5.334] DP. MOUNTING HOLES OPTIONAL SPACER PLATE 0.240 [6.096] 0.198 0.125 [3.175] TYPE 'K' FIELD [5.029] 2.688 [68.275] 0.275 [6.985] REPLACEABLE FEMALE CONNECTOR (TYP. 2 PLACES) 0.480 [12.192]

.220 [5.588] 0.550 [13.97] 0.776 0.500 [12.70] [19.71] 1.96 [49.78] .660 [16.764] .330 [8.382]

458 ACTIVE MULTIPLIERS – OUTLINE DRAWINGS (CONT.)

157345 157637

0.452 [11.481] **OPTIONAL ** INPUT VOLTAGE PIN 0.375 [9.525] OUTPUT 4X Ø.100 [Ø2.54] 1.100 [27.94] MOUNTING HOLES TYP. 0.452 0.017 [0.432] [11.481] ± .002 [0.051] 0.590 0.740 [14.986] [18.796] 0.202 [5.131] INPUT OUTPUT 0.060 [1.524] 0.075 [1.905] 0.425 [10.795] CHAMFER ± .007 [0.178] 0.037 [0.940] UNUSED 0.275 [6.985] 0.200 [5.08] 0.170 0.200 [5.08] [4.318] 0.370 0.370 [9.398] 0.008 [0.203] [9.398] ± .001 [0.025] 45° 0.32 [0.813] TYP. 0.047 [1.194] 0.445 0.410 [10.41] [11.303] 0.048 [1.219] TYP. 0.352 0.452 0.095 [2.413] [8.941] 0.008 0.202 [11.481] 0.200 [5.08] [0.203] [5.131] 0.250 [6.35] 0.300 [7.62]

0.008 [0.203] 0.008 [0.203] 0.075 [1.905] 0.226 [5.740] 0.377 [9.576] 0.445 [11.303] 0.452 [11.481] TIPLIER PRODUCTS

MUL 160057 160212

0.236 [5.994] 0.282 [7.163] 0.055 [1.397] Ø.073 [Ø1.85] MOUNTING .050 .820 [20.83] HOLES 0.590 [14.986] 0.480 [12.192] [1.27] .050 [1.27] (4 PLACES)

.222 [5.639] .222 [5.639] 2X 0.375 0.800 4X Ø0.080 [0.203] DIA. THRU [9.525] [20.32] MOUNTING HOLES .344 [8.738] .44 [11.18]

0.295 [7.493] IN OUT .460 [11.68] +V PCB 0.410 [10.414] .04 [1.02] 0.200 [5.08] 2X TYPE SMA FIELD .92 [23.37] REPLACEABLE FEMALE CONNECTOR

459 ACTIVE MULTIPLIERS – OUTLINE DRAWINGS (CONT.)

160833 161565

1.40 [35.56] .24 .12 [3.05] 1.00 [25.40] [6.10] +15V OUT IN .15 [3.81] .04 .60 [15.24] .16 [4.06] [1.02] .11 [2.79] .500 [12.70] 4X Ø.070 .48 .19 .44 .30 [7.62] [11.18] .70 [12.19] [4.83] .050 [Ø1.778] [17.78] [1.27] .050 [1.27] MOUNTING .90 HOLES 0-80 X .10 [2.54] DP .38 [22.86] .45 [11.43] MOUNTING HOLES [9.65] .16 [4.06] .168 [42.67] TYP. .067 [1.702] DIA. THRU F 2F MOUNTING HOLES .220 [5.588] .070 [1.778] DIA. THRU (4 PLACES) MOUNTING HOLES (2 PLACES) .32 [8.13]

.18 [4.57] .30 [7.62]

CIRCUIT BOARD .04 [1.02] .35 [8.89] .35 TYPE SMA FEMALE FIELD [8.89] MOUNTING SURFACE

REPLACEABLE CONNECTORS MUL (2 PLACES) TIPLIER PRODUCTS .31 [7.87] .18 [4.57]

SPACER MATERIAL: ALUMINUM MATERIAL: ALUMINUM FINISH: GOLD PLATED FINISH: IRRIDITE CL3

161566 162011

Ø.073 [Ø1.85] MOUNTING .050 .820 [20.83] HOLES [1.27] .050 [1.27] (4 PLACES)

.222 [5.639] .222 [5.639]

.344 [8.738] .44 [11.18]

IN OUT .460 [11.68] +V PC .04 [1.02]

.92 [23.37]

460 ACTIVE MULTIPLIERS – OUTLINE DRAWINGS (CONT.)

163124 163640

.560 [14.224] .160 [4.064] + V .240 [6.096]

.042 [1.067] 0.60 [1.52] .260 [6.604] IN Ø.070 [178] THRU .520 .436 0.500 [1.27] MTG. HOLE [13.208] [11.074] 0.050 [0.127] 0.050 [0.127] 4 PLACES RF IN 0.16 [0.406] RF OUT 0.32 0.220 F 2F .067 [1.702] DIA. THRU - V [0.813] MOUNTING HOLES [0.559] (4PLACES) OUT TYPE "K" OR "SMA" FIELD .280 [7.112] REPLACEABLE FEMALE CIRCUITRY CONNECTOR, 2 PLACES CIRCUIT BOARD .290 [7.366] .195 [4.953] 0.045 [0.114] .38 .100 [2.54] [9.65] TYP. OPTIONAL SPACER PLATE MOUNTING SURFACE NOTES: 1. Unit’s mounting surface shall be attached to a heatsink capable of dissipating the devices power consumption without exceeding the operating temperature limits. 2. Refer to the actual device specification sheet for bias requirements. Negative bias input voltage (v-) may not be included on certain models. 3. Unless noted on the specification sheet, when negative bias is required, do not power the unit with positive bias for more than one second without the negative bias being applied. TIPLIER PRODUCTS MUL

461 FREQUENCY MULTIPLIERS

Questions and Answers about...

FREQUENCY MULTIPLIERS

Q1: What do I need a frequency multiplier for?

A1: In general, a frequency multiplier translates an input frequency range to an output one, the output one being a multiple of the input. This is useful when an output signal is really needed higher than an available input source can supply. It could cost quite a lot to buy a source at higher frequencies. A better cost approach would be to use a less costly one, and just multiply the signal.

Q2: What specifications are important for a multiplier, and which ones should be given the most consideration?

A2: On page 380, some general rules and typical values are presented. Some important insights can be found by considering the way or system in which the multiplier will be used. It could be useful to examine the desired system specifications, in particular spurious rejection.

Q3: I need a custom multiplier, not shown in the catalog, what should be done next?

A3: Try to locate a somewhat similar product and identify the differences. Contact MITEQ for additional technical support. MUL

Q4: I have a military and/or space multiplier requirement, and I cannot find any indication that TIPLIERS MITEQ has produced such products. Is this a problem?

A4: MITEQ regularly gets such multiplier requirements. They are reviewed, and as such these custom multipliers are specific to a unique situation, and are not shown in our catalog.

Q5: I need a multiplier system, which includes non-multiplier type structures. Can MITEQ manufacture these type of systems and what sort of quantities, can MITEQ handle?

A5: A considerable amount of MITEQ’s multiplier business includes small quantity custom products. Depend- ing on future order potential and how much your budget can allow, all sorts of possibilities exist. Some of MITEQ’s largest multiplier orders fit in this category.

Q6: What system precautions are important when specifying multiplier component specifications?

A6: One or more multipliers are often employed to upconvert a lower frequency stable reference oscillator into the system microwave operating frequency. Since active gain and filter stages are often necessary, one must insure that all multiplier output harmonics of the input reference frequency are adequately suppressed and the output power to noise floor ratio is compatible with the system phase noise specification. Since one or more gain stages of an active multiplier are saturated, AM noise is not usually a consideration.

462 FREQUENCY MULTIPLIERS (CONT.)

Q7: What types of frequency multiplier circuits are available?

A7: In order of increasing complexity: • Single or single antiparralled pair Schottky diodes • Single-, double- or triple-balanced Schottky diodes with baluns • Active amplifiers and/or MMICS • SRD (step-recovery diode) circuits • Varactor diodes, resistive loaded • Varactor diodes, regenerative

Q8: What precaution is necessary when specifying a multiplier to be followed by an active (and saturated) gain stage?

A8: If the amplifier is high gain with large bandwidth and saturates at +10 dBm, then the highest level multiplier output will produce +10 dBm output. However, if the fifth harmonic is desired from the multiplier but the third is more efficient by 6 dB, then the 5X output will be suppressed by the gain difference. This can be avoided by filtering the third harmonic or utilizing a multiplier with tuned baluns (MITEQ type FEM, FOM).

Q9: Can ordinary double- or triple-balanced mixers be used as multipliers?

A9: Yes, particularly as doublers, when the RF and LO are the same input frequency and the SUM (2RF) is extracted from the highest frequency port of the mixer. The total input power should be sufficient to turn on the diodes. The MITEQ 4 to 40 GHz triple-balanced mixer is available with an internal power splitter to direct the input energy to the LO and IF port (2 to 20 GHz) and recover the 4 to 40 GHz output at the RF port.

Q10: When is it wise to use a Schottky diode multiplier and when is an SRD or varactor type more suitable? TIPLIER PRODUCTS

MUL A10: Schottky diode multipliers are lowest cost and require the least input power (+10 dBm). Output noise is at room temperature (KTBW). The resulting current waveforms, however, have a high duty cycle (i.e., square wave = 50%) and therefore, higher multiplier harmonics above the fifth decay quickly. Step-recovery diodes have impulsive waveforms with comb-like output spectrums. The input circuit is more complex requiring a compromise between bandwidth and efficient coupling to the low diode series resistance. The required input power is a function of the SRD capacitance and quickly rises with frequency (+20 dBm typical at 1 GHz). The hyper abrupt varactor diode (indistinguishable at high frequencies from the SRD) yields the highest output powers and efficiency, provided that unwanted sidebands are reactively terminated. MITEQ has successfully made efficient frequency doublers and prescalers (halfers) at 10 and 20 GHz.

463