标签: e2v

I don’t know if I've mentioned this before, but I'm tremendously interested in rockets and space probes and planets and solar systems and galaxies and the wonders of universe in general (I don’t like to limit myself). As you are no doubt aware, for the last couple of days the world has been buzzing with the news that, for the first time, scientists have confirmed small amounts of liquid water flowing on the surface of present-day Mars.   This raises the possibility that if life ever managed to claw its way up on Mars, then there may still be living organisms there now. If we were to detect life on another planet, this would dramatically change our perspective on... well, a lot of things, really.   The reason I'm waffling on about this here is that I was chatting with my chum Adam Taylor this morning. Adam never fails to surprise me when it comes to the cool imaging activities his company -- e2v in the UK -- is involved in. During today's conversation, for example, he casually mentioned that e2v played a part in the discovery of the Martian water.   It turns out that the Mars Reconnaissance Orbiter (MRO), which was launched in 2015 and which is currently orbiting Mars, contains something called the High Resolution Imaging Science Experiment (HiRISE). In turn, the HiRISE camera boasts e2v image sensors, which allow it to combine very high resolution and signal-to-noise ratio with a large swath width, thereby allowing it to collect images of unprecedented detail. It was HiRISE that captured the image below:   (Image courtesy of NASA / Jet Propulsion Laboratory / University of Arizona)   Scientists believe that the dark, narrow, downhill streaks in this image -- especially the fact that they are changing over time -- are evidence of water flowing on Mars.   Unfortunately, these satellite images are the closest we have at the moment, but I live in hopes that humans will visit and explore Mars in person in my lifetime. Meanwhile, with regard to the "Never-Before-Seen Close-Up Photo" promised in the title of this column, I offer you the following image:   (Image courtesy of Max Maxfield and Bruce Till)   How do I know this little scamp has never been seen before? Well, I feel confident in making this claim because my chum and graphics artist guru, Bruce Till, who sits in the office next to mine, just created it for me a few minutes ago. Hmmm, looking at this image is making me hungry; now I fancy a Mars Bar!

  型号 TC285 CCD201 生产厂家 TI (Phoenix) E2V 分辨率 1004 x 1002 1024 x 1024 像元尺寸 8um x 8um 13um x 13um 像元占空比 (H:V) 1:1 1:1 最大帧速率 30Hz 17Hz 最大像素速率 35MHz 20MHz 频谱响应范围 400nm~850nm 400nm~850nm 强光抗晕 (Antiblooming) 有 无 输出通道 1 2 敏感度 ( 典型 CCM) 5600V/Lux*sec 高 量子效率 较低 (65%) 高 (90%) 照明方式 前照式 背照式 输出倍增寄存器数 400 个 604 个 典型倍增增益 200( 最大 2000) 200( 最大 1000) 暗电流 ( 常温 ) 0.005nA/cm 2 0.001nA/cm 2 增益控制电压 低 (25V) 、可调 高 (40V) 、可调 动态范围 ( 常温 ) 宽(72dB) 宽 是否自带制冷 有 (TC285SPD-B0) 无 应用资料 较多 少 成本价格 较高 高 典型应用相机 1. Photometrics Cascade 1K (16bit-10MHz, -30 o C, Binning) 2. Andor iXon3 885 (14bit-13MHz, -80 o C, Binning) 1. Photometrics Cascade II (16bit-10MHz, -60 o C, Binning) 2. Andor iXon3 888 (14bit-10MHz, -80 o C, Binning) 主要应用领域 生物医学、夜视、天文、航空、显微、低照度等 注： CCM=Charge Carrier Multiplication ，电荷载体倍增

  型号 TC285 CCD201 生产厂家 TI (Phoenix) E2V 分辨率 1004 x 1002 1024 x 1024 像元尺寸 8um x 8um 13um x 13um 像元占空比 (H:V) 1:1 1:1 最大帧速率 30Hz 17Hz 最大像素速率 35MHz 20MHz 频谱响应范围 400nm~850nm 400nm~850nm 强光抗晕 (Antiblooming) 有 无 输出通道 1 2 敏感度 ( 典型 CCM) 5600V/Lux*sec 高 量子效率 较低 (65%) 高 (90%) 照明方式 前照式 背照式 输出倍增寄存器数 400 个 604 个 典型倍增增益 200( 最大 2000) 200( 最大 1000) 暗电流 ( 常温 ) 0.005nA/cm 2 0.001nA/cm 2 增益控制电压 低 (25V) 、可调 高 (40V) 、可调 动态范围 ( 常温 ) 宽(72dB) 宽 是否自带制冷 有 (TC285SPD-B0) 无 应用资料 较多 少 成本价格 较高 高 典型应用相机 1. Photometrics Cascade 1K (16bit-10MHz, -30 o C, Binning) 2. Andor iXon3 885 (14bit-13MHz, -80 o C, Binning) 1. Photometrics Cascade II (16bit-10MHz, -60 o C, Binning) 2. Andor iXon3 888 (14bit-10MHz, -80 o C, Binning) 主要应用领域 生物医学、夜视、天文、航空、显微、低照度等 注： CCM=Charge Carrier Multiplication ，电荷载体倍增