QHYCCD

QHY 268C PH SBFL - Cooled Back-Illuminated Color Camera - APS-C Sensor - 110058

Out of stock
SKU: QHY-110058
$2,207.00 CAD
Product details
  • SKU QHY-110058
Description

With the advantage of low readout noise and high-speed readout, CMOS technology has revolutionized astronomical imaging. A color, back-illuminated, high-sensitivity astronomical imaging camera and still image video camera is the ideal choice for astro-imagers.

The QHY268C PH is a cooled, back-illuminated color CMOS camera based on the Sony IMX571 sensor with true 16-bit A/D and 3.76μm pixels. This Sony sensor is an ideal CMOS sensor exhibiting no amplifier glow. 16-bit A/D gives high-resolution sampling of the whole full well range. Digitizing 0-65535 levels yields a smooth image with a continuous gradation of greyscale levels.

Features

1GB DDR3 image buffer

In order to provide smooth uninterrupted data transfer of the entire 26MP sensor at high speed, the QHY268 has 1GB DDR3 image buffer. The pixel count of the latest generation of CMOS sensors is very high resulting in greater memory requirements for temporary and permanent storage. 

The QHY268 has adopted a large-capacity memory of up to 1GB.  Data throughput is doubled. This large image buffer meets the needs of high-speed image acquisition and transmission of the new generation of CMOS, making shooting of multiple frames smoother and less stuttered, further reducing the pressure on the computer CPU.

Native 16 bit A/D: The Sony IMX571 sensor has native 16-bit A/D on-chip. The output is real 16-bits with 65536 levels. Compared to 12-bit and 14-bit A/D, a 16-bit A/D yields higher sample resolution and the system gain will be less than 1e-/ADU with no sample error noise and very low read noise.

BSI: One benefit of the back-illuminated CMOS structure is improved full well capacity. In the back- illuminated sensor the light is allowed to enter the photosensitive surface from the reverse side. In this case the sensor’s embedded wiring structure is below the photosensitive layer. As a result, more incoming photons strike the photosensitive layer and more electrons are generated and captured in the pixel well. This ratio of photon to electron production is called quantum efficiency. The higher the quantum efficiency the more efficient the sensor is at converting photons to electrons and hence the more sensitive the sensor is to capturing an image of something dim.

TRUE RAW Data: In the DSLR implementation there is a RAW image output, but typically it is not completely RAW.  Some evidence of noise reduction and hot pixel removal is still visible on close inspection.  This can have a negative effect on the image for astronomy such as the “star eater” effect. 

However,  QHY offers TRUE RAW IMAGE OUTPUT and produces an image comprised of the original signal only, thereby maintaining the maximum flexibility for post-acquisition astronomical image processing programs and other scientific imaging applications.

Zero Amplify Glow: This is also a zero amplifier glow camera.

Cooling & Anti-dew Control: In addition to dual stage TE cooling, QHYCCD implements proprietary technology in hardware to control the dark current noise. The optic window has built-in dew heater and the chamber is protected from internal humidity condensation. An electric heating board for the chamber window can prevent the formation of dew.

Sealing Technology: Based on almost 20-year cooled camera design experience, The QHY cooled camera has implemented the sealing control solutions. The sensor itself is kept dry with our silicon gel tube socket design for control of humidity within the sensor chamber. By the way, there’s no oil leaking.

Multiple Readout Modes:  Multiple Readout Modes are special for QHY 16-bit Cameras (QHY600/268/461/411).  Different readout modes have different driver timing, etc., and result in different performance.

You may find some types of thermal noise can change with time in some back-illuminated CMOS cameras. This thermal noises has the characteristic of the fixed position of typical thermal noise, but the value is not related to the exposure time.  Instead, each frame appears to have its own characteristics.  The QHY600/268/461/411 use an innovative suppression technology that can significantly reduce the apparent level of such noise.

UVLO Protection:  UVLO (Under Voltage Locking) is to protect the electronic device from damage caused by abnormally low voltages.

Our daily life experience tells us that the actual operational voltage of an electrical device must not significantly exceed the rated voltage, otherwise it will be damaged.

For such precision equipment as cameras, long-term work at too low input voltage can also be detrimental to the working life of the camera, and may even make some devices, such as power manager, burn up due to long-term overload. In the all-in-one driver and SDK after 2021.10.23 stable version, the camera will give a warning when the input voltage of the camera is below 11V.

Optimizing USB Traffic to Minimize Horizontal Banding: It is common behavior for a CMOS sensor to contain some horizontal banding. Normally, random horizontal banding can be removed with multiple frame stacking so it does not affect the final image. However, periodic horizontal banding is not removed with stacking so it may appear in the final image. By adjust the USB traffic in Single Frame mode or Live Frame mode, you can adjust the frequency of the CMOS sensor driver and it can optimize the horizontal banding appeared on the image. This optimized is very effective to remove the periodic banding in some conditions.

Reboot the camera by power off and on: The camera is designed to use the +12V to reboot the camera without disconnecting and reconnecting the USB interface. This means that you can reboot the camera simply by shutting down the +12V and then powering it back on. This feature is very handy for remote controlling the camera in an observatory. You can use a remotely controlled power supply to reboot the camera. There is no need to consider how to reconnect the USB in the case of remote control.

Multiple Readout Modes and Curves: 

Multiple Readout Modes are special for QHY 16-bit Cameras (QHY600/268/461/411).  Different readout modes result in different performance. These readout modes are currently supported in the ASCOM, SharpCap and N.I.N.A.

Photographic DSO Mode (Mode #0)

This mode is suitable for most DSO imaging situations. Since there is a drop in the noise between Gain 25 and Gain 26 (unity gain), we recommend it as default gain setting; however, gain0 is also good enough for a 16-bit sensor.

High Gain Mode  (Mode #1)

This mode is something like double native iso of some new digital cameras, whose danamic range can greatly incerase at the vary high iso value, like iso800, iso3200, etc. The high gain mode provide such improvement for QHYCCD 16bit cameras.

We recommend you choose this mode when you have to capture at high gain, for example, a vary dark object. Please note the switch point of HGC/LGC of QHY600/268/461 is 56. That means you must set Gain 56 to make the best of it.

Extended Fullwell Mode (Mode#2)

With a pixel size of 3.76um, these sensors already have an impressive full well capacity of 51ke. Nevertheless, QHYCCD has implemented a unique approach to achieve a full well capacity higher than 51ke- through innovative user controllable read mode settings. In Extended Fullwell Mode, the QHY600 can achieve an extremely large full-well charge value of nearly 80ke- and the QHY268 can achieve nearly 75ke-. Greater full-well capacity provides greater dynamic range and large variations in magnitude of brightness are less likely to saturate. 

2CMS Modes

Extended Fullwell Mode-2CMS (Mode#3)

Photographic DSO Mode-2CMS (Mode#4)

High Gain Mode-2CMS (Mode#5)

Based on the three basic modes above, 2CMS mode can greatly reduce readout noise by secondary sampling while keeping the same full well value and system gain. We prefer 2CMS modes than basic modes in astrophotography. By the way, the recommend gain values are the same as their basic modes.

Specifications

Model QHY268C PH
CMOS Sensor SONY IMX571
Mono/Color Color
FSI/BSI BSI
Pixel Size 3.76μm*3.76μm
Effective Pixel Area 6252*4176
Total Pixel Area 6280*4210 (include optical black area and overscan area)
Effective Pixels 26 Megapixels
Sensor Size APS-C
A/D Native 16-bit (0-65535 greyscale) A/D
Full Well Capacity (1×1, 2×2, 3×3) Standard Mode
51ke-
Extended Full Well Mode
80ke-
Frame Rates Full Resolution:

 

6.8FPS@8bit, 6FPS@16bit

in 12 bit High Speed Mode: 8-bit, (12-bit out), 14.5fps max

ROI:

2048lines, 13.6FPS@8bit, 11.5FPS@16bit
1080lines, 25.4FPS@8bit, 19.5FPS@16bit
768lines, 35FPS@8bit, 25FPS@16bit
480lines, 50FPS@8bit, 34FPS@16bit
Readout Noise 1.1e- to 3.5e-
(5.3e- to 7.4e- in Extended Full Well Mode)
Dark Current 0.0005 e-/pixel/sec@-20℃,
0.001 e-/pixel/sec@-10℃
Exposure Time Range 30μs-3600sec
Recommend Gain 30 (PH Mode, or Extended Full Well Mode)
56 (High Gain Mode)
Amp Control Zero Amplifer Glow
Shutter Type Electronic Rolling Shutter
Computer Interface USB3.0
Built-in Image Buffer 1GB DDR3 Memory Buffer
Cooling System Dual Stage TEC cooler:
– Long exposures (> 1 second) typically -35℃ below ambient
– Short exposure (< 1second) high FPS, typically -30℃ below ambient(Test temperature +20℃)
Optic Window Type AR+AR High Quality Multi-Layer Anti-Reflection Coating
Telescope Interface Support M54 or M48 (Combined with adapters )
Back Focal Length

 14.5mm(±0.2)
Anti-Dew Heater Available
Humidity Sensor No, available in QHY268M only
Firmware/FPGA remote Upgrade Available via Camera USB port
Weight 810g

 

What's in the Box

  • Camera
  • Locking Power Cable
  • USB 3.0 Cable
  • 12V Power Adapter
  • AV Power Cable
  • Desiccant Tube
  • M54 to 2” Nosepiece
  • 5mm M54 Adapter
  • 3mm M54 Adapter
  • 3mm M54-M42 Adapter
  • Drive Download Instructions

Readout Mode #0 (Photographic Mode)

Readout Mode #1 (High Gain Mode)

Readout Mode #2 (Extended Full Well Mode)

Readout Mode #3 (Extend Full Well Mode-2CMS)

Readout Mode #4 (Photographic Mode-2CMS)

Readout Mode #5 (High Gain Mode-2CMS)