DOCSLIB.ORG

Picmicro Advanced Analog Microcontrollers

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text

Load more

LOOKING FOR FASTER CONVERSION AND MORE ACCURACY IN YOUR 8-BIT MCU DESIGN? Microchip Technology Inc. offers the broadest range of high- PICmicro MCUs are ideal for applications demanding high performance analog 8-bit microcontrollers (MCUs) that allow levels of analog integration. PICmicro MCU advanced analog you to increase system performance and analog-to-digital (A/D) features include: resolution while decreasing component count and cost. To meet – 10- and 12-bit Resolution A/D Converter demanding mixed-signal design requirements, Microchip has integrated advanced analog technologies, peripherals and Offering higher A/D resolution than most 8-bit industry MCUs features into a single-chip solution. These devices offer 10- and results in more precise voltage measurements. It also allows 12-bit A/D converter channels to streamline system integration for higher levels of system integration and cost savings. and reduce cost without compromising A/D performance. – Programmable Low Voltage Detect (LVD) Microchip offers PICmicro®MCUs in a wide variety of Allows the low voltage detection range to be chosen at integrated solutions and in pin counts ranging from 8 to 84. system level design via software for more reliability and Sized right to meet your application requirements, the PICmicro security of operation. MCU provides the option for a fully-integrated A/D with up to – Programmable Brown-out Detect/Reset (BOD) 12-bits resolution for your high-performance analog designs. Programmable BOD offers the system level design engineer This simplifies electronic circuitry design, improves system more flexibility and reliability to meet their system reliability and lowers power consumption. requirements. The high-performance, advanced analog PICmicro MCUs – On-Chip Voltage Reference provide performance and versatility to meet the most Ensures accuracy of the analog peripherals. The On-Chip demanding requirements of today's cost-sensitive analog Voltage Reference provides stable voltage supply for sensor designs. Plus, with FLASH memory technology, Microchip’s devices and ratio metric conversion from non-linear sensor PIC16F87X MCU program memory can be updated or waveforms. reprogrammed at low voltages. Remote Sensor Application PIC16C77X 4.096V ON-CHIP INTERNET VOLTAGE (TCIP/IP) 2.048V REFERENCE RF INTERFACE MODEM BRIDGE 12-BIT SENSOR A/D CONVERTER INFRARED etc. LOW VOLTAGE DETECT This simplified block diagram depicts a MCU-based system that utilizes the advanced analog capabilities of the PICmicro MCU to interface to a pressure sensor. PICmicro HIGH-PERFORMANCE ANALOG MICROCONTROLLER SOLUTIONS Plus, the advanced digital features of a RS-485 USART are integrated for multi-drop data acquisition applications, and Master Mode I2C or SPI communications capability for peripheral expansion. The PIC16C773 and PIC16C774 allow direct precision interface to the power supply and device under control. Available in 28-, 40- and 44-pin packages, the PIC16C773 and PIC16C774 are ideal for applications such as intelligent gas sensors, data acquisition and logging, motor control, power conditioning and environmental monitoring. The PIC18CXX2 MCU family includes the PIC18C242, PIC18C442, PIC18C252 and PIC18C452. These devices extend the Microchip’s PIC16C770 and PIC16C771 are the world’s first 18- and 20-pin PICmicro MCU's MCUs to integrate 12-bit A/D converters. high-performance RISC architecture with a 16-bit instruction set and high levels of peripheral The PIC16C717, PIC16C770 and PIC16C771 are the world's integration in 28- to 40-pin packaged devices. They offer priority first 18- and 20-pin MCUs with on-chip 10- and 12-bit A/D levels for interrupts, various serial interface capabilities, up to converters. These devices offer a new level of advanced analog 8 channels of 10-bit A/D converter and multi-timers. The precision to systems requiring small MCU footprints. Coupling PIC18CXX2 family is suited for applications that require these advanced analog features with a rich set of digital extremely fast execution of complex software. peripherals (three timers, CCP, programmable BOD, LVD, The PIC16F87X FLASH MCU bandgap reference voltage generator and serial interface with 2 ™ ™ family features a wide operating Master Mode I C and SPI support) makes the PICmicro MCU voltage, making them ideal for family ideal for high-performance/cost-sensitive analog AC- or battery-powered applications. applications such as remote sensors, safety and security This family includes the 28-pin monitoring systems, and battery chargers. PIC16F873 and PIC16F876, and The PIC16C773 and PIC16C774 the 40-/44-pin PIC16F874 and provide the MCU industry's most PIC16F877. The devices provide a advanced 8-bit mixed-signal system 5- to 8-channel 10-bit A/D converter, RS-485 type USART for solution available. The devices multi-drop data acquisition applications, Master Mode I2C or SPI substantially reduce discrete logic communications capability for peripheral expansion, up to components, related circuitry area 5 MIPS performance at 20 MHz and three timers. Applications and overall system cost. With an range from networked communications, POS terminals and integrated 6- to 10-channel 12-bit utility metering to power management, programmable machine A/D converter, the PIC16C773 and PIC16C774 fit designs controls and automotive body controllers. The PIC16F87X also requiring high-performance in a smaller space, or where higher supports program memory self programming over a wide levels of advanced analog integration are being demanded of voltage range allowing remote programming with no limitations the system design. They incorporate highly sophisticated analog on the application's operating voltage and clock frequency. peripheral technology including programmable BOD, programmable LVD and bandgap reference voltage generator. COMPREHENSIVE DEVELOPMENT TOOL SYSTEMS AND SUPPORT Microchip is committed to providing useful and innovative development tools that allow designers to meet design and time-to-market requirements. All PICmicro MCUs are supported by the MPLAB®ICE 2000 Universal In-Circuit Emulator. This high-performance real-time in-circuit emulator also features the sophisticated MPLAB Integrated Development Environment (IDE). Interchangeable processor modules and device adapters allow the emulator system to be easily configured to emulate different processors. MPLAB ICE 2000 emulates voltages as low as 2.0 volts and can emulate at full speed. Operating in the Microsoft®Windows®environment, MPLAB ICE 2000 gives users the flexibility to edit, compile and emulate all from a single user interface – at no additional cost. MPLAB In-Circuit Debugger (ICD) Evaluation Kit. MPLAB ICD uses the in-circuit debugging capability of the Microchip’s MPLAB ICE 2000 Universal In-Circuit Emulator for PIC16F87X family and Microchip's In-Circuit Serial ™ PICmicro MCUs provides superior performance, advanced Programming capability to debug source code in the debugging capabilities and ease of use. application, debug hardware in real-time and program a target PIC16F87X device. Operating under MPLAB IDE, MPLAB ICD offers real-time code execution, in-circuit debugging, built-in exactly like a real device. This is very important when it programmer and 3.0 to 5.5 volts operating range. System comes to I/O drive strengths, AC timings and oscillator components include an in-circuit debugging module, header, operation. There are no protection devices to interfere with demo board and MPLAB software. The main advantage of a the operation of the circuit and no cables or interconnect debugger is that the device itself is the emulator. The debug devices to load the circuit. Other support and development circuitry is already on each processor. The designer benefits tools include PRO MATE®II Universal Device Programmer by having an interface to the external circuitry that will behave and PICSTART®Plus Development Programmer. PICmicro Advanced Analog MCU Products* Program Memory E2PROM Data Data 10-bit Max. Brown- (Words) Memory RAM ADC Speed I/O out Product OTP FLASH Bytes Bytes Channels MHz Ports Detection Timers Communications ICSP™ Other Features Pins PIC16C717 2048x14 – – 256 6 20 16 Yes, PBOD 1-16 bit, I2C/SPI Yes ECCP, MSSP, 9Bit, 18, 20 2-8 bit, 1-WDT VREF,LVD PIC16C770 2048x14 – – 256 6 (12-bit) 20 16 Yes, PBOD 1-16 bit, I2C/SPI Yes ECCP, MSSP, 9Bit, 20 2-8 bit, 1-WDT VREF,LVD PIC16C771 4096x14 – – 256 6 (12-bit) 20 16 Yes, PBOD 1-16 bit, I2C/SPI Yes ECCP, MSSP, 9Bit, 20 2-8 bit, 1-WDT VREF,LVD PIC16C773 4096x14 – – 256 6 (12-bit) 20 22 Yes, PBOD 1-16 bit, USART/I2C/SPI Yes MSSP, 9Bit, 2 CCP,28 2-8 bit, 1-WDT VREF,PLVD PIC16C774 4096x14 – – 256 10 (12-bit) 20 33 Yes, PBOD 1-16 bit, USART/I2C/SPI, Yes MSSP, 9Bit, 40, 44 2-8 bit, 1-WDT PSP 2 CCP,VREF,PLVD PIC16F873 – 4096x14 128 192 5 20 22 Yes 1-16 bit, USART/I2C/SPI Yes CCP, MSSP, 9Bit 28 2-8 bit, 1-WDT PIC16F874 – 4096x14 128 192 8 20 33 Yes 1-16 bit, USART/I2C/SPI, Yes CCP, MSSP, 9Bit 40, 44 2-8 bit, 1-WDT PSP PIC16F876 – 8192x14 256 368 5 20 22 Yes 1-16 bit, USART/I2C/SPI Yes CCP, MSSP, 9Bit 28 2-8 bit, 1-WDT PIC16F877 – 8192x14 256 368 8 20 33 Yes 1-16 bit, USART/I2C/SPI, Yes CCP, MSSP, 9Bit 40, 44 2-8 bit, 1-WDT PSP PIC18C242 8192x16 – – 512 5 40 23 Yes, PBOD 3-16 bit, USART/I2C/ Yes 2xECCP,LVD, 1-8 bit, 1-WDT SPI/PSP 8x8 Multiply, PLL 28 PIC18C442 8192x16 – – 512 5 40 34 Yes, PBOD 3-16 bit, USART/I2C/ Yes 2xECCP,LVD, 1-8 bit, 1-WDT SPI/PSP 8x8 Multiply, PLL 40, 44 PIC18C252 16384x16 – – 1536 8 40 23 Yes, PBOD 3-16 bit, USART/I2C/ Yes 2xECCP,LVD, 1-8 bit, 1-WDT SPI/PSP 8x8 Multiply, PLL 28 PIC18C452 16384x16 – – 1536 8 40 34 Yes, PBOD 3-16 bit, USART/I2C/ Yes 2xECCP,LVD, 1-8 bit, 1-WDT SPI/PSP 8x8 Multiply, PLL 40, 44 Abbreviations: 9Bit = 9-bit Serial Addressing Mode; CCP = Compare/Capture/Pulse Width Modulation; ECCP = Enhanced Capture/Compare/Pulse Width Modulation; EMA = External Memory Addressing; LVD = Low Voltage Detection; MSSP = Master Synchronous Serial Port/I2C/SPI; PBOD = Programmable Brown-out Detection; PSP = Parallel Slave Port; VREF = On-Chip Voltage Reference; WDT = Watchdog Timer *Current as of December 1, 2000.
Recommended publications
  • Portfolio Holdings Listing Select Semiconductors Portfolio As of June

    Portfolio Holdings Listing Select Semiconductors Portfolio As of June

    Portfolio Holdings Listing Select Semiconductors Portfolio DUMMY as of August 31, 2021 The portfolio holdings listing (listing) provides information on a fund’s investments as of the date indicated. Top 10 holdings information (top 10 holdings) is also provided for certain equity and high income funds. The listing and top 10 holdings are not part of a fund’s annual/semiannual report or Form N-Q and have not been audited. The information provided in this listing and top 10 holdings may differ from a fund’s holdings disclosed in its annual/semiannual report and Form N-Q as follows, where applicable: With certain exceptions, the listing and top 10 holdings provide information on the direct holdings of a fund as well as a fund’s pro rata share of any securities and other investments held indirectly through investment in underlying non- money market Fidelity Central Funds. A fund’s pro rata share of the underlying holdings of any investment in high income and floating rate central funds is provided at a fund’s fiscal quarter end. For certain funds, direct holdings in high income or convertible securities are presented at a fund’s fiscal quarter end and are presented collectively for other periods. For the annual/semiannual report, a fund’s investments include trades executed through the end of the last business day of the period. This listing and the top 10 holdings include trades executed through the end of the prior business day. The listing includes any investment in derivative instruments, and excludes the value of any cash collateral held for securities on loan and a fund’s net other assets.
  • LPC47N267 Product Brief

    LPC47N267 Product Brief

    LPC47N267 100-Pin LPC Super I/O with X-Bus Interface Product Features • Enhanced Digital Data Separator - 2 Mbps, 1 Mbps, 500 Kbps, 300 Kbps, 250 • 3.3 Volt Operation (5V tolerant) Kbps Data Rates • Programmable Wakeup Event Interface - Programmable Precompensation Modes (IO_PME# Pin) • Serial Ports • SMI Support (IO_SMI# Pin) - Two Full Function Serial Ports • GPIOs (29) - High Speed NS16C550 Compatible UARTs • Four IRQ Input Pins with Send/Receive 16-Byte FIFOs • X-Bus Interface - Supports 230k and 460k Baud - Supports up to 4 external components - Programmable Baud Rate Generator - Supports I/O cycles (No Memory Support) - Modem Control Circuitry - 8-Bit Data Transfer • Infrared Communications Controller - 16-Bit Address Qualification - IrDA v1.2 (4Mbps), HPSIR, ASKIR, Con- - Write Protection for each component sumer IR Support • XNOR Chain -2 IR Ports • PC99 and ACPI 1.0b Compliant - 96 Base I/O Address, 15 IRQ Options and 3 • 100-pin STQFP Package DMA Options • Intelligent Auto Power Management • Multi-Mode Parallel Port with ChiProtect • 2.88MB Super I/O Floppy Disk Controller - Standard Mode IBM PC/XT, PC/AT, and PS/2 - Licensed CMOS 765B Floppy Disk Controller Compatible Bidirectional Parallel Port - Software and Register Compatible with - Enhanced Parallel Port (EPP) Compatible - Microchip's Proprietary 82077AA Compatible EPP 1.7 and EPP 1.9 (IEEE 1284 Compliant) Core - IEEE 1284 Compliant Enhanced Capabilities - Supports One Floppy Drive Directly Port (ECP) - Configurable Open Drain/Push-Pull Output - ChiProtect Circuitry for
  • Microchip Technology Announces Financial Results for Third Quarter of Fiscal Year 2020

    Microchip Technology Announces Financial Results for Third Quarter of Fiscal Year 2020

    EXHIBIT 99.1 NEWS RELEASE INVESTOR RELATIONS CONTACT: J. Eric Bjornholt -- CFO..... (480) 792-7804 MICROCHIP TECHNOLOGY ANNOUNCES FINANCIAL RESULTS FOR THIRD QUARTER OF FISCAL YEAR 2020 ◦ Net sales of $1.287 billion, down 3.8% sequentially and down 6.4% from the year ago quarter. The midpoint of our updated net sales guidance provided on January 6, 2020 was $1.285 billion. ◦ On a GAAP basis: gross margin of 61.0%; operating income of $131.2 million; net income of $311.1 million; and EPS of $1.20 per diluted share. Our guidance provided on December 3, 2019 was GAAP (loss) earnings per share of $(0.03) to $0.04 per diluted share. ◦ On a Non-GAAP basis: gross margin of 61.5%; operating income of $452.1 million and 35.1% of net sales; net income of $340.8 million and EPS of $1.32 per diluted share. Our guidance provided on December 3, 2019 was Non-GAAP EPS of $1.19 to $1.30 per diluted share. ◦ End-market demand of $1.324 billion was $36.1 million higher than net sales. ◦ Cash flow from operations of $395.5 million. ◦ Paid down $257.0 million of debt in the December 2019 quarter. Cumulatively paid down almost $2 billion of debt over the last six quarters. ◦ Record quarterly dividend declared of 36.70 cents per share. CHANDLER, Arizona - February 4, 2020 - (NASDAQ: MCHP) - Microchip Technology Incorporated, a leading provider of smart, connected and secure embedded control solutions, today reported results for the three months ended December 31, 2019 as summarized in the following table: (in millions, except per share amounts and percentages) Three Months Ended December 31, 2019 Net sales $1,287.4 % of Net % of Net GAAP Sales Non-GAAP1 Sales Gross margin $785.5 61.0% $791.2 61.5% Operating income $131.2 10.2% $452.1 35.1% Other expense $(120.6) $(89.5) Income tax (benefit) provision $(300.5) $21.8 Net income $311.1 24.2% $340.8 26.5% Net income per diluted share $1.20 $1.32 (1) See the "Use of Non-GAAP Financial Measures" section of this release.
  • AN2534 PAC193X Integration Notes for Microsoft® Windows® 10 Driver Support Author: Razvan Ungureanu TABLE 2: REVISION HISTORY Microchip Technology Inc

    AN2534 PAC193X Integration Notes for Microsoft® Windows® 10 Driver Support Author: Razvan Ungureanu TABLE 2: REVISION HISTORY Microchip Technology Inc

    AN2534 PAC193X Integration Notes for Microsoft® Windows® 10 Driver Support Author: Razvan Ungureanu TABLE 2: REVISION HISTORY Microchip Technology Inc. Rev# Date Description 1.0 20-June-2017 The information in this INTRODUCTION document apply to the This document describes the basic steps for integrating PAC193X driver releases: the PAC193X DC Power Monitor device in a Microsoft® 1.0, 1.1 and 1.2 Windows® 10 host system in order to enable support of the Windows® 10 PAC193X driver. HARDWARE INTEGRATION As the PAC193X device can be used in multiple ways The hardware integration must first address all the and in different system configurations, there are some electrical details specified in the device data sheet. For 2 specific hardware and BIOS configuration details that example, the device VDD IO must match the I C bus need to be addressed before loading the Windows® voltage. But the following hardware notes address only device driver. the hardware details that need specific configuration in ® The details about the PAC193X Windows® 10 device order to make them compatible with the Windows 10 driver loading, feature set and software interfaces are device driver: included in the PAC193X Windows® 10 Driver User’s •I2C bus controller Windows® support Guide that complements the information presented by • PAC193X VDD and SLOW/ALERT pin connections this document. • Channel shunt resistor values . TABLE 1: GLOSSARY OF TERMS AND • Channel polarity ACRONYMS I2C Bus Controller Windows® Support Acronym Term 2 E3 Energy Estimation Engine The PAC193X device I C/SMBus interface is by default configured in the I2C Mode. Mind that the SMBus EMI Energy Metering Interface protocol is not currently supported by Windows®.
  • Stoxx® Global Automation & Robotics Index

    Stoxx® Global Automation & Robotics Index

    STOXX® GLOBAL AUTOMATION & ROBOTICS INDEX Components1 Company Supersector Country Weight (%) SNAP 'A' Technology United States 4.24 NVIDIA Corp. Technology United States 2.80 Nidec Corp. Technology Japan 2.42 HEXAGON B Technology Sweden 2.38 TERADYNE Technology United States 2.31 KLA Technology United States 2.23 MARVELL TECHNOLOGY Technology United States 2.16 Intuitive Surgical Inc. Health Care United States 2.12 ADVANCED MICRO DEVICES Technology United States 2.12 Qualcomm Inc. Technology United States 2.09 Apple Inc. Technology United States 2.06 Advantest Corp. Technology Japan 2.05 LASERTEC Technology Japan 2.04 Garmin Ltd. Consumer Products & Services United States 2.02 Emerson Electric Co. Industrial Goods & Services United States 2.02 Microchip Technology Inc. Technology United States 1.98 Ametek Inc. Industrial Goods & Services United States 1.96 Toyota Industries Corp. Automobiles & Parts Japan 1.96 Xilinx Inc. Technology United States 1.95 SERVICENOW Technology United States 1.88 DASSAULT SYSTEMS Technology France 1.82 Rockwell Automation Corp. Industrial Goods & Services United States 1.74 Fanuc Ltd. Industrial Goods & Services Japan 1.74 Autodesk Inc. Technology United States 1.68 Keyence Corp. Industrial Goods & Services Japan 1.63 Ansys Inc. Technology United States 1.61 HALMA Industrial Goods & Services Great Britain 1.56 PTC INC Technology United States 1.53 Omron Corp. Technology Japan 1.52 OPEN TEXT (NAS) Technology Canada 1.49 COGNEX Industrial Goods & Services United States 1.48 Yaskawa Electric Corp. Industrial Goods & Services Japan 1.40 SAP Technology Germany 1.40 MINEBEA MITSUMI Industrial Goods & Services Japan 1.24 Intel Corp.
  • MCP3426/7/8 16-Bit, Multi-Channel ΔΣ Analog-To-Digital Converter with I2C™ Interface and On-Board Reference

    MCP3426/7/8 16-Bit, Multi-Channel ΔΣ Analog-To-Digital Converter with I2C™ Interface and On-Board Reference

    MCP3426/7/8 16-Bit, Multi-Channel ΔΣ Analog-to-Digital Converter with I2C™ Interface and On-Board Reference Features Description • 16-bit ΔΣ ADC with Differential Inputs: The MCP3426, MCP3427 and MCP3428 devices - 2 channels: MCP3426 and MCP3427 (MCP3426/7/8) are the low noise and high accuracy - 4 channels: MCP3428 16 Bit Delta-Sigma Analog-to-Digital (ΔΣ A/D) Con- verter family members of the MCP342X series from • Differential Input Full Scale Range: -V to REF Microchip Technology Inc. These devices can convert +V REF analog inputs to digital codes with up to 16 bits of reso- • Self Calibration of Internal Offset and Gain per lution. Each Conversion The MCP3426 and MCP3427 devices have two • On-Board Voltage Reference (V ): REF differential input channels and the MCP3428 has four - Accuracy: 2.048V ± 0.05% differential input channels. All electrical properties of - Drift: 15 ppm/°C these three devices are the same except the • On-Board Programmable Gain Amplifier (PGA): differences in the number of input channels and I2C - Gains of 1,2, 4 or 8 address bit selection options. • INL: 10 ppm of Full Scale Range These devices can output analog-to-digital conversion • Programmable Data Rate Options: results at rates of 15 (16-bit mode), 60 (14-bit mode), or 240 (12-bit mode) samples per second depending on - 15 SPS (16 bits) the user controllable configuration bit settings using the - 60 SPS (14 bits) two-wire I2C serial interface. During each conversion, - 240 SPS (12 bits) the device calibrates offset and gain errors • One-Shot or Continuous Conversion Options automatically.
  • PICMASTER™ Support of Microsoft ® Windows™

    PICMASTER™ Support of Microsoft ® Windows™

    PICMASTER Support of Microsoft Windows DDE AN584 PICMASTER™ Support of Microsoft® Windows™ DDE The PICMASTER system supports Windows Dynamic 5. You will see the trace buffer fill with instructions and Data Exchange (DDE). This feature allows the contents data if those instructions were executed and trace of the trace buffer to be transferred to other windows enabled. If you do not see any instructions in the applications such as Microsoft Excel™. This feature is trace buffer, check the Trace Settings in (1) and look invaluable to control systems designers who would like for loops or deadlock situations that would prevent to plot real-time data to debug and fine tune an applica- your program from executing these instructions. tion. This application note will show how to set this up Note: PICMASTER must be running and the trace and graph system data. buffer open with data displaying in order to use DDE for other Windows applications (such as THE TRACE BUFFER Microsoft Excel as described in the next section). The PICMASTER contains a 8K x 40 bit trace buffer. The fields within this buffer are broken up into three SETTING UP EXCEL categories: After starting Excel with a blank spread sheet, select 100 (1) Current Address of instruction 16-Bits (ADDRESS) rows in the first column by pressing the left mouse button (2) Data/Opcode Field 16-Bits (DATA) and holding it down to drag across all cells. Next Type the following string in the box: (3) External Logic Analyzer inputs 8-Bits (EXT) 5 ————— =PICMASTR|’c:\path\test.hex’!’data 0 99’ 40-Bits and hit CNTRL+SHIFT+ENTER Any instruction can be optionally traced or not traced; the The format for this command is as follows: trace for each instruction is enabled by the “T” field on the =PICMASTR|’<hex_file>‘!’<string> far left column of the program memory dump window.
  • AN1630A USB to I2C Bridge Reference Guide

    AN1630A USB to I2C Bridge Reference Guide

    AN1630A USB to I²C Bridge Reference Guide Author: Dale Herman Microchip Technology INTRODUCTION Microchip’s SCSI USB to I²CTM bridge devices provide a USB to I²C bridge. The I²C bridge utilizes SCSI pass-through commands using the Mass Storage Class driver. The internal hub can have e.g., three ports enabled with two exposed externally. This document includes the following topics: • Example of a USB to I²C Bridge Environment on page 1 • SCSI Pass-through Commands on page 3 EXAMPLE OF A USB TO I²C BRIDGE ENVIRONMENT Figure 1 provides an example how the USB to I²C bridge can be integrated in an environment. FIGURE 1: USB TO I²C BRIDGE ENVIRONMENT (EXAMPLE) Automotive Head Unit / Navigation USB Cable Microchip USB Hub with SCSI USB to I²C Bridge 3-Port USB 2.0 HS Hub I²C Bridge Conversion USB HS Flash Media Reader USB 2.0 Down-stream Port 2.0 Down-stream USB Port 2.0 Down-stream USB USB I²C nReset Cable USB Device I²C Slave 2014 Microchip Technology Inc. DS00001630A-page 1 AN1630A Figure 2 depicts which function blocks are involved in such an example environment. FIGURE 2: USB TO I²C BRIDGE AS FBLOCK IN THE EXAMPLE ENVIRONMENT Head Unit Application Operating System Application Protocol USB - I²C Bridge Other USB Mass Storage HUB Driver HID Class Device Class Class USB EHCI Driver or Equivalent DS00001630A-page 2 2014 Microchip Technology Inc. AN1630A SCSI PASS-THROUGH COMMANDS General Description of the Write_I²C_Stream Command A Write I²C Stream command sends any length of data over the I²C interface.
  • IEEE 802.3Da SPMD TF Meeting May 19, 2021 Prepared by Peter Jones

    IEEE 802.3Da SPMD TF Meeting May 19, 2021 Prepared by Peter Jones

    IEEE 802.3da SPMD TF meeting May 19, 2021 Prepared by Peter Jones Presentations posted at: https://www.ieee802.org/3/da/index.html Agenda/Admin - Chad Jones All times in Pacific Time (PT) 7:01am: The Chair reviewed the agenda in https://www.ieee802.org/3/da/public/051921/8023da_agenda_051921.pdf. The Chair asked if there were any corrections or additions to the agenda. There being no corrections or additions, the agenda stands approved. The Chair asked if anyone hasn’t had a chance to review the minutes for April 21, 2021. None responded. The Chair asked if there were any change to be made to the April 21, 2021 minutes. None responded. The April 21, 2021 minutes were approved by unanimous consent. 7:09am: Call for patents was made, no one responded. 7:14am: opening agenda slides complete. The meeting moves on to presentations. Presentations/Discussion. 7:14am: LTspice Model Validation Chris DiMinico, MC Communications/PHY-SI LLC/SenTekse/Panduit Bob Voss, Panduit Paul Wachtel, Panduit 7:21am: presentation done, start of Q&A. 7:30am: Q&A done. 7:30am: Startup sequence Michael Paul, ADI 8.05am: presentation & Q&A done. 8:05am: Editors comments George Zimmerman, CME Consulting/various 8:28am: Closing remarks Next meeting: May 26, 2021 , 7:00am PT. Meeting closed – 8:31am PT Attendees (from Webex + emails) Name Employer Affiliation Attended 05/19 Alessandro Ingrassia Canova Tech Canova Tech y Anthony New Prysmian Group Prysmian Group y Bernd Horrmeyer Phoenix Contact Phoenix Contact y Bob Voss Panduit Corp. Panduit Corp. y Brian Murray Analog Devices Inc.
  • Microchip Technology Inc

    Microchip Technology Inc

    Microchip Technology Inc. Watchdog Report ™ MCHP (NASDAQ Global) | CIK:827054 | United States | SEC llings The new model for duciary analysis Sep 24, 2021 Jan 1, 2020 Jan 1, 2016 RECENT PERIOD HISTORICAL PERIOD Key Facts 10-Q led on Aug 3, 2021 for period ending Jun 2021 Business address: Chandler, Arizona, United States Reporting Irregularities RECENT HISTORICAL Industry: Semiconductor and Related Device Manufacturing (NAICS Financial Restatements 334413) SEC ler status: Large Accelerated Filer as of Jun 2021 Revisions Index member: S&P 500, Russell 1000 Out of Period Adjustments Market Cap: $45.3b as of Sep 24, 2021 Late Filings Annual revenue: $5.44b as of Mar 31, 2021 Impairments Corporate Governance Changes in Accounting Estimates CEO: Ganesh Moorthy since 2021 Disclosure Controls CFO: Eric J. Bjornholt since 2009 1st level Internal Controls Board Chairman: Steve Sanghi since 1993 Critical / Key Audit Matters Audit Committee Chair: NOT AVAILABLE Anomalies in the Numbers 2nd level RECENT HISTORICAL Benford's Law Auditor: Ernst & Young LLP since 2001 Outside Counsel (most recent): Wilson Sonsini Goodrich & Rosati Beneish M-Score Osborn Maledon PA Accounting Disclosure Complexity 3rd level Securities & Exchange Commission Concerns RECENT HISTORICAL SEC Reviewer: (unknown) 4th level SEC Oversight SEC Letters to Management Revenue Recognition Non-GAAP Measures Litigation & External Pressures RECENT HISTORICAL Signicant Litigation Securities Class Actions Shareholder Activism Watchdog Research, Inc., offers both individual and group subscriptions, Cybersecurity data feeds and/or custom company reports to our subscribers. Management Review Subscribe: We have delivered 300,000 public company reports to over RECENT HISTORICAL 27,000 individuals, from over 9,000 investment rms and to 4,000+ public CEO Changes company corporate board members.
  • Microsoft Top 100 Production Suppliers (Based on FY14 Spend for Commercially Available Hardware Products)

    Microsoft Top 100 Production Suppliers (Based on FY14 Spend for Commercially Available Hardware Products)

    Microsoft Top 100 Production Suppliers (Based on FY14 spend for commercially available hardware products) AAC ACOUSTIC TECHNOLOGIES INTEL ALLEGRO MICROSYSTEMS, INC. INTERNATIONAL BUSINESS MACHINES (IBM ALPS ELECTRIC COMPANY CORP.) AMD INTERNATIONAL RECTIFIER AMPEREX TECHNOLOGY, LTD. JOHNSON ELECTRIC GROUP AMPHENOL KIONIX, INC. ANALOG DEVICES KYOCERA/AVX ASKEY COMPUTER CORPORATION LAIRD TECHNOLOGIES ATMEL CORPORATION LELON ELECTRONICS (SUZHOU) CO., LTD BIZLINK TECHNOLOGY INC (BIZCONN) LG CHEM BOYD CORPORATION LITE-ON BRADY MARLOW INDUSTRIES, INC. CHICONY POWER MARVELL SEMICONDUCTOR COMPEQ MANUFACTURING CO., LTD. MICROCHIP TECHNOLOGY COOLER MASTER, INC. MICRON TECHNOLOGY, INC. COOPER BUSSMANN MOLEX, INC. CYMMETRIK MONOLITHIC POWER SYSTEMS, INC. CYNTEC CO., LTD. MURATA MANUFACTURING CO., LTD. DELTA ELECTRONICS, INC. NEWMAX TECHNOLOGY CO., LTD. DIGITAL OPTICS VISTA POINT NICHICON CORPORATION DIODE, INC. NIDEC CORPORATION E&E MAGNETICS PRODUCTS, LTD. NUVOTON TECHNOLOGY CORPORATION ELLINGTON ELECTRONICS TECHNOLOGY NVIDIA CORPORATION FAIRCHILD SEMICONDUCTOR CORPORATION NXP SEMICONDUCTORS FLEXTRONICS ON SEMICONDUCTOR FOXCONN OSRAM FOXLINK PALCONN, PALPILOT INTERNATIONAL CORP. FREESCALE PANASONIC GOERTEK, INC. PEGATRON CORPORATION HANNSTAR BOARD PHILIPS PLDS HITACHI-LG DATA STORAGE PRIMESENSE HONDA PRINTING QUALCOMM HYNIX SEMICONDUCTOR REALTEK SEMICONDUCTOR CORPORATION INFINEON RF MICRO DEVICES, INC. INNOVATOR ELECTRONIC SHENZHEN CO., LTD RICHTEK TECHNOLOGY CORP. ROHM CORPORATION SAMSUNG DISPLAY SAMSUNG ELECTRONICS SAMSUNG SDI SAMSUNG SEMICONDUCTOR SEAGATE SHEN ZHEN JIA AI MOTOR CO., LTD. SHENZHEN HORN AUDIO CO., LTD. SHINKO ELECTRIC INDUSTRIES CO., LTD. STARLITE PRINTER, LTD. STMICROELECTRONICS SUNG WEI SUNUNION ENVIRONMENTAL PACKAGING CO., LTD TDK TE CONNECTIVITY TEXAS INSTRUMENTS TOSHIBA TPK TOUCH SOLUTIONS, INC. UNIMICRON TECHNOLOGY CORP. UNIPLAS (SHANGHAI) CO., LTD. UNISTEEL UNIVERSAL ELECTRONICS INCORPORATED VOLEX WACOM CO., LTD. WELL SHIN TECHNOLOGY WINBOND WOLFSON MICROELECTRONICS, LTD. X-CON ELECTRONICS, LTD. YUE WAH CIRCUITS CO., LTD.
  • MICROCHIP TECHNOLOGY INCORPORATED (Exact Name of Registrant As Specified in Its Charter)

    MICROCHIP TECHNOLOGY INCORPORATED (Exact Name of Registrant As Specified in Its Charter)

    UNITED STATES SECURITIES AND EXCHANGE COMMISSION Washington, D.C. 20549 FORM 10-K (Mark One) Annual Report pursuant to Section 13 or 15(d) of the Securities Exchange Act of 1934 For the fiscal year ended March 31, 2019 OR Transition report pursuant to Section 13 or 15(d) of the Securities Exchange Act of 1934 For the transition period from _________ to __________ Commission File Number: 0-21184 MICROCHIP TECHNOLOGY INCORPORATED (Exact Name of Registrant as Specified in Its Charter) Delaware 86-0629024 (State or Other Jurisdiction of Incorporation or Organization) (IRS Employer Identification No.) 2355 W. Chandler Blvd., Chandler, AZ 85224-6199 (Address of Principal Executive Offices, Including Zip Code) (480) 792-7200 (Registrant's Telephone Number, Including Area Code) Securities registered pursuant to Section 12(b) of the Act: Title of Each Class Trading Symbol Name of Each Exchange on Which Registered Common Stock, $0.001 Par Value Per Share MCHP NASDAQ® Global Market Securities registered pursuant to Section 12(g) of the Act: None Indicate by check mark if the Registrant is a well-known seasoned issuer, as defined in Rule 405 of the Securities Act. Yes No Indicate by check mark if the Registrant is not required to file reports pursuant to Section 13 or Section 15(d) of the Act. Yes No Indicate by checkmark whether the Registrant: (1) has filed all reports required to be filed by Section 13 or 15(d) of the Securities Exchange Act of 1934 during the preceding 12 months (or for such shorter period that the registrant was required to file such reports), and (2) has been subject to such filing requirements for the past 90 days.