A Security System Specification

FLIR Systems, Inc.

FC-Series S Camera

Architect & Engineering Specifications

FLIR Systems, Inc. Document Number: 427-0081-00-13 Commercial Systems Version: 100 70 Castilian Drive Issue Date: March 2013 Goleta, CA 93117 1-877-773-3547 http://www.cvs.flir.com/security/

Revision Date Notes 100 03/19/2013 Initial release A&E Specification FLIR Systems, Inc. FC-Series Camera

PART 1 - NOT USED

PART 2 - PRODUCTS

2.1 Thermal Security Camera

A. Functional Description

1. The Thermal Security Camera shall not depend on any visible or invisible (infrared) illumination or image intensifier to “see” i.e. produce images. The Thermal Security Camera shall be totally passive and not produce any energy or emit light in any bandwidth. The Thermal Security Camera shall allow the user to clearly identify images in the total absence of light.

2. The Thermal Security Camera shall allow the user to see through smoke and light fog and to view the thermal patterns and contrast in the scene.

3. The Thermal Security Camera shall utilize a Vanadium Oxide (VOx) uncooled microbolometer responding in the LWIR (Long Wave Infrared) spectral range of 7.5 – 13.5 μm which is beyond what is visible to the human eye.

4. The Thermal Security Camera shall not be susceptible to permanent damage after imaging the sun. This is in contrast to some systems based on amorphous silicon detector technology which can be permanently damaged when viewing the sun or even reflections of the sun.

5. The Thermal Security Camera shall not utilize shutters to prevent damage from the sun.

6. The Thermal Security Camera shall include a lens or window that is temperature controlled to prevent dew, frost and ice accumulation.

7. The Thermal Security Camera shall not utilize dynamic apertures to protect the image sensor because these mechanisms reduce sensitivity for an extended period of time, thus reducing the Thermal Security Camera performance as required for security installations.

8. The Thermal Security Camera shall provide athermal optics that automatically adjust to ambient temperature changes, and therefore do not require re-adjustment and/or thermal refocusing.

9. The Thermal Security Camera shall not be susceptible to “image blooming” caused by bright lights as are image intensifiers and visible spectrum cameras.

10. The Thermal Security Camera shall be available in the following configurations, with fixed anti-reflection coated Germanium lenses with the Field of View (FOV) and resolutions as indicated: 2 A&E Specification FLIR Systems, Inc. FC-Series Camera Lens Resolution FOV Pixel (pixels) Pitch 35 mm 320 x 240 9° H x 7° V 17µm 35 mm 320 x 240 13° H x 10° V 25µm 19 mm 320 x 240 24° H x 19° V 25µm 13 mm 320 x 240 34° H x 28° V 25µm 9 mm 320 x 240 48° H x 39° V 25µm 7.5 mm 320 x 240 63° H x 50° V 25µm 35 mm 640 x 480 18° H x 14° V 17µm 19 mm 640 x 480 32° H x 26° V 17µm 13 mm 640 x 480 45° H x 37° V 17µm 9 mm 640 x 480 69° H x 56° V 17µm 7.5 mm 640 x 480 90° H x 69° V 17µm Table 1: Field of View (FOV) 11. The range of the Thermal Security Camera shall be defined at three levels consisting of:

a. Detection – In order to detect if an object is present or not, its critical dimension needs to be covered by 1.5 or more pixels.

b. Recognition – Recognizing an object is defined as seeing what type of object it is. This means being able to determine if the object is a person, a car or a truck. In order to recognize an object it needs to be subtended by at least 6 pixels across its critical dimension.

c. Identification – Identifying the object is defined as seeing if it is a man/woman or a man carrying a shovel verses a man carrying a rifle. In order to identify an object it needs to be subtended by at least 12 pixels.

3 A&E Specification FLIR Systems, Inc. FC-Series Camera 12. The approximate DRI (Detection, Recognition, and Identification) ranges for a vehicle and a human target with each of the lenses listed in Tables 2 & 3.

Lens Detection Recognition Identification 35 mm 3250 835 410 35 mm 2700 m 680 m 340 m 19 mm 1250 m 315 m 158 m 13 mm 1000 m 250 m 125 m 9 mm 700 m 175 m 88 m 7.5 mm 570 m 140 m 72 m 35 mm 3300 m 840 m 415 m 19 mm 1950 m 500 m 250 m 13 mm 1340 m 340 m 170 m 9 mm 880 m 220 m 108 m 7.5 mm 730 m 180 m 92 m Table 2: DRI range for Vehicle (2.3 m x 2.3 m critical dimension)

Lens Detection Recognition Identification 35 mm 1080 272 136 35 mm 880 m 225 m 112 m 19 mm 440 m 110 m 55 m 13 mm 330 m 82 m 41 m 9 mm 230 m 57 m 28 m 7.5 mm 185 m 43 m 23 m 35 mm 1100 m 274 m 138 m 19 mm 640 m 160 m 80 m 13 mm 440 m 112 m 56 m 9 mm 285 m 71 m 36 m 7.5 mm 235 m 60 m 30 m Table 3: DRI range for Human Target (1.8 m x 0.5 m critical dimension) 13. An online site security planning tool shall be available to assist the user in selecting the correct cameras and designing a video surveillance system. The tool shall utilize Google Earth maps saved as jpeg images to allow the user to place cameras on the site / buildings and simulate the actual field of view of any camera to visually see the difference between each camera / lens combination for detection, recognition and identification. The tool shall work the same as the one at this URL: http://raven.flirops.com/.

14. The Noise Equivalent Temperature Difference (NETD) is the measure of the smallest object temperature that can be detected by the thermal image sensor relative to the system noise. The measurement is usually quantified in units of mK. This is the most common Figure of Merit of a thermal imaging system and a true measurement of the thermal camera’s sensitivity. The Thermal Security Camera image sensor with a clear aperture f/1.0 lens shall provide a NETD of <50mK.

15. The Thermal Security Camera shall include Auto Digital Detail Enhancement (Auto DDE) which is an advanced non-linear image

4 A&E Specification FLIR Systems, Inc. FC-Series Camera processing algorithm. The Auto DDE function is fully automatic and requires no input or adjustment from the user. The Auto DDE shall enhance the image detail to match the total dynamic range of the original image allowing details to be visible to the user even in scenes with low or high thermal contrast. Auto DDE will increase the probability of detection of low contrast images.

16. The Thermal Security Camera shall utilize Non-Uniformity Correction (NUC) which is a set of compensation factors for each pixel. NUC shall enable the following features and benefits: a. Eliminate the need for FPA (Focal Plane Array) temperature stabilization. b. Allow for near instantaneous camera turn-on. c. Reduced system complexity and power consumption. d. Allow for a wider operating temperature range.

17. The Thermal Security Camera shall include Automatic Gain Control (AGC) circuitry to compensate for scene variations, improve image quality by avoiding saturation and distortion, and to balance signal levels prior to display to maximize image quality.

18. The Thermal Security Camera shall have a Wide Dynamic Range (WDR) capability to compensate for scenes that include extreme temperature ranges (such as when the sun is in the FOV) without losing details in the terrestrial foreground.

19. The Thermal Security Camera shall feature both White-Hot and Black-Hot operating modes. In the White-Hot (default) mode warmer images will be displayed in white or lighter shades than cooler or background areas. In the Black-Hot mode warmer objects will be displayed as black or dark gray compared to cooler objects.

20. The Thermal Security Camera shall provide IP network video to the following specifications:

Live Video Web Page Two Independent Streams MPEG4, H.264, and MJPG Unicast and Multicast support ONVIF 2.0 Table 4: Streaming IP Video Output Specifications

NTSC PAL D1: 720x480 D1: 720x576 4CIF: 704x480 4CIF: 704x576 VGA: 640x480 Native: 640x512 SIF: 352x240 Q-Native: 320x256 QVGA: 320x240 CIF: 352x288 QCIF: 176x144 5 A&E Specification FLIR Systems, Inc. FC-Series Camera Table 5: NTSC/PAL Streaming Image Sizes

21. The Thermal Security Camera shall provide standard NTSC or PAL analog composite video output (factory configured) to allow it to function as a direct replacement for daylight camera and to connect directly to digital video recorders, encoders and monitoring equipment. The analog video signal shall be available via a BNC video output connector.

22. The Thermal Security Camera shall provide a local analog video output connector (RCA type). This feature shall allow the installer to test the Thermal Security Camera and view live video during installation and set-up without interrupting the main video output to the overall security system.

23. The Thermal Security Camera outdoor enclosure with sunshield and mounting base shall meet IP66 and IP67 rating for dust and water ingress.

24. The mounting base shall be provided with two 1/4x20 holes on the bottom of the camera and two 1/4x20 holes on the top for mounting to a pedestal or wall mount. Alternatively the camera can be mounted with four M5 x 0.8 threaded fasteners to the bottom of the camera.

25. The Thermal Security Camera shall allow cable connections through a rear cable gland assembly. There shall be an optional concealed cable wall mount accessory available, and the Thermal Security Camera shall allow cable connections through the base of the camera when the camera is mounted to the concealed cable wall mount.

26. All cable connections shall be made inside of the enclosure. The enclosure shall be provided with liquid-tight sealed cable gland fittings for analog video, Ethernet, serial control, and power cables.

27. The camera enclosure shall include grounding and surge protection. A separate Earth ground connection shall be made inside the enclosure to a designated grounding lug. The Earth ground conductor may be run as part of the power cable bundle.

28. The Thermal Security Camera shall meet vibration testing according to IEC 60068-2-27: 10g shock pulse with a 11ms half- sine profile.

29. The Thermal Security Camera shall feature an IP network interface, built-in Ethernet port, built-in web browser interface / Nexus server for device set- up, configuration and control.

30. The Thermal Security Camera shall use the embedded Nexus server to provide plug and play integration with FLIR Sensors Manager (FSM) software, to enable sophisticated sensor management capabilities such as geo-referenced mapping, video analytics, slew-on-alarm and radar slew-to cue. 6 A&E Specification FLIR Systems, Inc. FC-Series Camera 31. The Thermal Security Camera shall provide two independent IP network streams (channels) of user selectable MPEG-4, H.264 or M-JPEG digital video.

32. From a computer or other device, the Thermal Security Camera shall support set-up, configuration and control as follows: a. Support a standard web browser interface. b. Provide a software utility such as FLIR Sensors Manager (FSM) which shall be included with each Thermal Security Camera. c. Support for third-party systems using the Nexus Software Development Kit (SDK) and a Common Gateway Interface (CGI) Application Programming Interface (API). d. Configuration settings shall include settings for the video CODEC, cameras sensors settings, etc.

33. The thermal security camera shall be ONVIF compliant and provide an IP network interface that is based on open standards to insure compatibility with a wide range of third-party video players and Video Management Systems (VMSs), such as, but not limited to, Milestone, Genetec and ONSSI.

34. The Thermal Security Camera shall operate as a hybrid device by providing both analog video (NTSC or PAL) simultaneously with IP video. This dual- mode operation will allow the camera to provide video to both analog and IP networks at one time.

7 A&E Specification FLIR Systems, Inc. FC-Series Camera

B. Technical Description

1. The Thermal Security Camera shall meet the following minimum requirements:

Sensor Type Long-life, Uncooled VOx Microbolometer Spectral Response 7.5 to 13.5μm Thermal Sensitivity <50mK f/1.0 clear aperture Pixel Pitch 320x240 models: 25μm 35mm 320x240 model: 17μm 640x480 models:17μm Composite Video NTSC or PAL, 75ohm BNC Output Live Video Web Page Available IP Network Streaming MPEG-4, H.264, M-JPEG Video Formats Independent Streaming Two IP Video Channels Ethernet Interface RJ-45 User Control Interface Ethernet control via FLIR Sensors Manager (FSM), the Nexus SDK, the Nexus CGI commands, ONVIF, Milestone, Genetec, and ONSSI Input Voltage PoE (IEEE 802.3af-2003), PoE+( IEEE 802.3at-2009 standard), 11-56VDC, 12-38VAC Power Consumption VDC: 5 W nominal at 24 VDC, Peak at 24 VDC: 21W (w/heaters) VAC: 8 VA nominal at 24 VAC Peak at 24 VAC: 29VA (w/heaters) Inrush Current <5 A for DC power supply with slew rate > 10 ms <19 A for AC power supply with slew rate > 4.17 ms Operating Temperature -50°C to 70°C (-58° F to 158° F) continuous Range -40°C to 70°C (-40° F to 158° F) cold start Storage Temperature -55°C to 85°C (-67° F to 185° F) Range Lens Heater Thermostatically Controlled Enclosure Rating IP-66 and IP-67 Weight ~ 1.8kg (4.0 lbs) w/o sunshield, ~ 2.2kg (4.8) with sunshield Dimensions (L, W, H) 10.2" x 4.5" x 4.2" w/o sunshield, 259mm x 114mm x 106mm w/o sunshield 11.1" x 5.1" x 4.5" with sunshield, 282mm x 129mm x 115mm with sunshield

8 A&E Specification FLIR Systems, Inc. FC-Series Camera The Thermal Security Camera shall be a FLIR FC-Series Camera.