X-ray sensors
Best-in-class sensing solutions enable x-ray equipment to render more accurate images with better contrast while limiting noise and distortion.
Digital x-ray solutions
ams OSRAM is a leader in computed tomography and digital x-ray solutions. We design and manufacture imaging sensing solutions which offer outstanding precision, high acquisition speeds, low noise and ultra-low power consumption. This enables manufacturers of scanning equipment to produce sharp images while exposing people to a low dose of radiation. Our portfolio covers medical, security and industrial x-ray applications. Our ambition is to evolve both our solutions and expertise to an unprecedented level of image accuracy, while enhancing convenience and safety for users.
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CT sensors
Medical professionals are constantly pushing CT imaging equipment manufacturers to provide better quality images allowing for more accurate diagnosis of a patient’s condition, while keeping x-ray dosage to a minimum to reduce the risk to the patient’s health when undergoing a scan. New generations of detector solutions from ams OSRAM are enabling equipment makers to achieve both these goals simultaneously, allowing reductions in x-ray doses while reducing noise and distortion in CT images.
The key to ams OSRAM detector superior performance is the optimization of the sensitive signal chain that includes photodiodes, interconnect and the high-speed ADC, by means of proprietary circuits and technologies that allow achieving an unprecedented level of performance.
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Digital x-ray
Digital X-ray equipment is widely used in general radiography, mammography and interventional radiology. The flat panel detectors (FPDs) integrated in this equipment must produce high-resolution images with low noise. ams OSRAM solutions for these FPDs help digital X-ray equipment manufacturers to produce accurate images and to increase scanning rates. Our product portfolio includes high-speed readout circuits and gate drivers optimized for line times as low as 15µs. These devices help to increase the frame rate in dynamic X-ray applications such as fluoroscopy. For static applications using portable and battery-powered FPDs, ams OSRAM offers readout circuits which dissipate as little as 1.1mW per channel, allowing radiologists to perform more X-ray exposures before the detector has to be recharged.
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X-ray sensors product list
| Device name | Description | Product Area | Product Type | Channels/Input channels input | Integration time min. | Input related noise typ. | Power consumption per channel min. | Resolution | Package | Function |
| ams AS5912 CT Detector Interface | The AS5912 is an ultra-low noise, 512-channel low power current to digital converter that enables the readout of photodiodes of a CT detector with highest sensitivity. The output currents of 512 photodiodes are converted simultaneously into digital without any dead time resulting in no charge loss on the inputs. The AS5912 combines current-to-voltage integration and A/D conversion for 512-channels in one device. The ADC architecture with its low-noise integrators, coarse quantizer, sample-and-hold and fine quantizer guarantee lowest input related noise of maximum 0.29 fC (low noise mode) at an input current range of 0.5 µA. The input current range of the ADC is selectable between 0.5 µA and 1 µA.<br><br>The AS5912 supports two supply concepts: a single analog and true ground supply, in both modes the photodiodes are zero biased for ultra-low dark current of the photodiode. In true ground mode, the AS5912 operates at ±1.5 V dual analog supply while in single supply mode only a single analog supply of +3.0 V is needed. The device detects automatically the chosen supply concept. No external components are required for supply decoupling. To reduce PCB area and simplify the assembly process, decoupling capacitors for supply and reference voltages are integrated in the 23 x 15 mm² FBGA package. The on-chip LDOs, reference voltages and a temperature sensor minimize the external component requirements and reduces the bill of material.<br><br>Full-scale range, integration time and power mode are configurable over a SPI-compatible serial interface as well as the digital output modes of the LVDS interface. In low power mode, the power dissipation can be minimized down to 1.25 mW per channel for reduced self-heating of the CT detector. The adjustable integration time down to 51 µs allow very high frame rates. | Sensor solutions | X-Ray Sensors | 512 | 51 µs | 0.29 | 1.25 mW | 26 bit | FBGA (23 x 15mm) | x-ray sensing |
| ams AS5920M Photon Counting Module | Product status: Pre-Production<br> The AS5920M is a 72x24 pixel, four-side buttable module solution for photon counting applied for spectral computed tomography detectors. The 1728-channel proprietary Buttable System-In-Package (BSIP) integrates three AS5920 photon counting ICs as well as passive components.<br> The BSIP allows on the top side to form electrical connections to the direct conversion CdTe or CZT sensor material, which converts each X-ray photon into charge pulses. The bottom side of the BSIP forms the digital interface to the FPGA, supply connections as well as the thermal heat dissipation to the carrier.<br> During a CT scan, the AS5920 IC counts the X-ray photon generated charge pulses with an amplitude proportional to the energy deposited by the photon. 576-channel per AS5920 discriminates the incoming photon energy by counting the number of pulses exceeding 5 different energy thresholds. The threshold levels are adjustable by 8-bit DACs with a step size of typ. 0.7 keV/LSB, the number of comparators enabled per channel are selectable for power optimizations. Lowest power dissipation with all 5 comparators enabled is as low as typ. 0.64 mW/pixel in non-paralyzable mode having BLR enabled and typ. 0.58 mW/pixel in paralyzable mode with only static leakage compensation.<br> A 15-bit counter register accumulates the comparator output events and transmits 14/16-bit LVDS data within an integration time of minimum 104 µs. During its maximum frame rate of 9615 Fps, the AS5920 transfers the output data via a high-speed LVDS interface to the FPGA, the device operates up to an input count rate of 250 Mcps per pixel (2 Gcps/mm²). The AS5920 has both paralyzable and non-paralyzable counting mode implemented that are selectable via SPI. In paralyzable mode, it allows for a maximum output count rate of 15 Mcps/pixel (120 Mcps/mm²) at 25 keV and exceeding 40 Mcps/pixel (>320 Mcps/mm²) in non-paralyzable mode.<br> The signal chain of the AS5920 with its low-noise charge sensitive amplifier (CSA) and its high-speed shaper allows for lowest electronic noise of 330 electrons resulting in an ASIC-intrinsic energy resolution of the measured photon of 3.5 keV FWHM.<br> The photon counting IC AS5920 features an on-chip voltage reference and internal temperature sensor and is embedded in the AS5920M. The AS5920M is delivered as 1728-channel, 4-side buttable module integrating three ICs in one 24.52 mm x 8.75 mm Buttable System-In-Package (BSIP). Pixel sizes of the BSIP are 341 µm x 365 µm and customizable for pixel pitch of 340 µm and above. The performance temperature range of AS5920 and AS5920M is specified from 20°C to 70°C. Gain deeper insights about <strong><a href=https://ams-osram.com/innovation/technology/photon-counting target="_blank">Photon Counting</a></strong> | Sensor solutions | X-Ray Sensors | 1728 | 104 µs | 330 | 0.58 mW | 16 bit | 4-Side Buttable System-In-Package (BSIP) | x-ray sensing |
| ams AS5952M CT Sensor Module | Product status: Pre-Production<br><br> The AS5952 is a sensor chip for 64-slice CT detectors that combines the photodiodes and the readout circuit on a single CMOS chip. This sensor solution, which includes an array of 32 x 8 photodiodes with ultra-low dark current and a 256-channel ADC side-by-side, allows the assembly of the pixel array on three adjacent edges of the device. Two AS5952 ICs can be placed in Z-direction enabling the design of CT detectors with 40 mm of Z-coverage in ISO center.<br><br>The AS5952 has a sensor dimension in Z-direction of 36.125 mm with a pixel dimension of 1.130x1.002 mm². Pixel dimensions can be customized on request. The sensor can be directly assembled on a substrate using a wire bonding process for manufacturing of a CT module.<br><br>Improved low dose performance can be achieved because of superior dark current of max. 1 pA due to the near zero offset voltage across the photodiode. The input-related noise is very low, a max. noise level of 0.36 fC can be reached including photodiode for an input current range of 200 nA.<br><br>The max. power dissipation of 1.46 mW per channel in normal mode and 1.23 mW per channel in low power mode reduces self-heating effects and lowers the overall cost of cooling the system. An internal reference voltage and bias generator reduces the bill of material. Featuring on-chip photodiodes, the AS5952 offers a cost-optimized solution for 64-slice CT detectors.<br><br>The digital data readout can be accessed via a 110 MHz LVDS interface. A SPI interface is used for device configuration such as mode of operation, input current range, selection of reference voltage and enabling the calibration mode. An integrated temperature sensor enables monitoring of the junction temperature. The AS5952 is delivered as die on foil on frame.<br><br>In addition we are offering the AS5952M. This module consists of 3x AS5952 integrated circuits, which are mounted onto a substrate and connected with wire bonding protected by glob top. The interface is on the bottom side through a flex connector that accepts a standard 0.3 mm thick Flexible Printed Circuit (FPC). All required passive components are located on the bottom side of the substrate. The module is available both with and without scintillator array. Watch the <strong><a href="https://youtu.be/C5KEOwT4Q8o" target="_blank">product video</a></strong> | Sensor solutions | X-Ray Sensors | 256 | 80 µs | 0.36 | 1.23 mW | 26 bit | module on substrate | x-ray sensing |
| ams AS5850A Digital X-ray Flat Panel Readout IC | The AS5850A is a 16-bit, 256-channel low-noise charge-to-digital converter designed for use in digital X-ray systems. The high degree of programmability enables system performance optimization in a wide range of applications. The combination of fast speed, low noise and low power consumption maximizes the image quality and minimizes patient dose, exposure whilst improving the time to market. <br> Each channel front-end consists of a charge sensitive amplifier (CSA) and a correlated double sampler (CDS), that removes offset and flicker noise from the signal, which is then converted to digital. A fast and reliable LVDS interface transmits the output digital data off-chip. Built-in diagnostic functionalities enable error detection in the signal chain. Voltage references and a temperature sensor are included on the chip. An SPI interface allows easy programming of the device parameters. <br> Four different power modes allow the user to minimize the current consumption for the chosen speed. Line times of 20, 28.5, 40 and 80 μs require as little as 3.1, 2.6, 1.6 and 1.1 mW per channel respectively. A special ADC operation mode is also available, that decreases the minimum line time to 15 μs without increasing the power consumption. Additionally, it is possible to add together the charges in pairs of adjacent channels; with this binning, the fastest achievable line time is 10 μs. | Sensor solutions | X-Ray Sensors | 256 | 15 µs | 500 | 3.1 mW | 16 bit | chip-on-flex | x-ray sensing |
| ams AS5850B Digital X-ray Flat Panel Readout IC | <div><font color="#46555f">The AS5850B is a 16-bit, 256-channel low-noise charge-to-digital converter designed for use in digital X-ray systems. The high degree of programmability enables system performance optimization in a wide range of applications. The combination of fast speed, low noise and low power consumption maximizes the image quality and minimizes patient dose, exposure whilst improving the time to market.</font></div><div><span style="background-color: transparent; color: rgb(70, 85, 95); font-family: inherit;">Each channel front-end consists of a charge sensitive amplifier (CSA) and a correlated double sampler (CDS), that removes offset and flicker noise from the signal, which is then converted to digital. A fast and reliable LVDS interface transmits the output digital data off-chip. Built-in diagnostic functionalities enable to locate the source of errors in the signal chain from the detector to the data acquisition system. Voltage references and a temperature sensor are included on the chip. An SPI interface allows easy programming of the device parameters.</span></div><div><span style="background-color: transparent; color: rgb(70, 85, 95); font-family: inherit;">Four different power modes allow the user to minimize the current consumption for the chosen speed. Line times of 20, 28.5, 40 and 80 μs require as little as 3.1, 2.6, 1.6 and 1.1 mW per channel respectively. A special ADC operation mode is also available, that decreases the minimum line time to 15 μs without increasing the power consumption. Additionally, it is possible to add together the charges in pairs of adjacent channels; with this binning, the fastest achievable line time is 10 μs.</span></div> | Sensor solutions | X-Ray Sensors | 256 | 15 µs | 500 | 3.1 mW | 16 bit | chip-on-flex (ACF bonding + standard connector) | x-ray sensing |
| ams AS5851B Digital X-ray Flat Panel Readout IC | <div>The AS5851B is a 16-bit, 256-channel low-noise charge-to-digital converter designed for use in digital X-ray systems. The high degree of programmability enables system performance optimization in a wide range of applications. The combination of fast speed, low noise and low power consumption maximizes the image quality and minimizes patient dose, exposure whilst improving the time to market.</div><div>Each channel front-end consists of a charge sensitive amplifier (CSA) and a correlated double sampler (CDS), that removes offset and flicker noise from the signal, which is then converted to digital. A fast and reliable LVDS interface transmits the output digital data off-chip. Built-in diagnostic functionalities enable to locate the source of errors in the signal chain from the detector to the data acquisition system. Voltage references and a temperature sensor are included on the chip. An SPI interface allows easy programming of the device parameters.</div><div>Two different power modes allow the user to minimize the current consumption for the chosen speed. Line times of 40 and 80 μs require as little as 1.6 and 1.1 mW per channel respectively. Additionally, it is possible to add together the charges in pairs of adjacent channels; with this binning, the fastest achievable line time is 20 μs.</div> | Sensor solutions | X-Ray Sensors | 256 | 40 µs | 500 | 1.6 mW | 16 bit | chip-on-flex (ACF bonding + standard connector) | x-ray sensing |
| ams AS5852B Digital X-ray Flat Panel Readout IC | <div>The AS5852B is a 16-bit, 256-channel low-noise charge-to-digital converter designed for use in digital X-ray systems. The high degree of programmability enables system performance optimization in a wide range of applications. The combination of fast speed, low noise and low power consumption maximizes the image quality and minimizes patient dose, exposure whilst improving the time to market.</div><div>Each channel front-end consists of a charge sensitive amplifier (CSA) and a correlated double sampler (CDS), that removes offset and flicker noise from the signal, which is then converted to digital. A fast and reliable LVDS interface transmits the output digital data off-chip. Built-in diagnostic functionalities enable to locate the source of errors in the signal chain from the detector to the data acquisition system. Voltage references and a temperature sensor are included on the chip. An SPI interface allows easy programming of the device parameters.</div><div>A line time of 80 μs requires as little as 1.1 mW per channel. Additionally, it is possible to add together the charges in pairs of adjacent channels; with this binning, the fastest achievable line time is 40 μs.</div> | Sensor solutions | X-Ray Sensors | 256 | 80 µs | 500 | 1.1 mW | 16 bit | chip-on-flex (ACF bonding + standard connector) | x-ray sensing |
| ams AS5900 CT Detector Interface | The AS5900 device is a low noise, 128-channel current-to-digital converter that enables the readout of the photodiodes with highest sensitivity. High-resolution CT imaging can be achieved up to 26-bits resolution. Its 128-low-noise and high linear converter channels provide an increased gray scale, improved contrast and reduce artifacts of 3D CT images. The low power consumption of 1mW per channel reduces self-heating effects and the overall power consumption of the system. An integrated temperature sensor allows the calibration of temperature drifts of the X-ray detector modules. | Sensor solutions | X-Ray Sensors | 128 | 50 µs | 0.51 | 1 mW | 26 bit | FBGA248 (10 x 10mm) | x-ray sensing |
| ams AS5911 CT Detector Interface | <div>The AS5911 is an ultra-low noise, 256-channel low power current to digital converter that enables the readout of photodiodes of a CT detector with highest sensitivity. The output currents of 256 photodiodes are converted simultaneously into digital without any dead time resulting in no charge loss on the inputs. The AS5911 combines current-to-voltage integration and A/D conversion for 256-channels in one device. The ADC architecture with its low-noise integrators, coarse quantizer, sample and hold and fine quantizer guarantee lowest input related noise of maximum 0.29 fC (low noise mode) at an input current range of 0.5 μA. The input current range of the ADC is selectable between 0.5 μA and 1 μA.<br><br></div><div>The AS5911 supports two supply concepts: a single analog and true ground supply, in both modes the photodiodes are zero biased for ultra-low dark current of the photodiode. In true ground mode, the AS5911 operates at ±1.5 V dual analog supply while in single supply mode only a single analog supply of +3.0 V is needed. The device detects automatically the chosen supply concept. No external components are required for supply decoupling. To reduce PCB area and simplify the assembly process, decoupling capacitors for supply and reference voltages are integrated in the 14 x 14 mm² FBGA package. The on-chip LDOs, reference voltages and a temperature sensor minimize the external component requirements and reduces the bill of material. The AS5911 features on-chip calibration functions for parameters such as offset voltage, linearity, offset charge and leakage current. This allows to automatically set the photodiode and the front-end at their ideal operating point, compensating for offsets and non-linearities of the signal chain.</div><div><br></div><div>Full-scale range, integration time and power mode are configurable over a SPI-compatible serial interface as well as the digital output modes of the LVDS interface. In low power mode, the power dissipation can be minimized down to 1.25 mW per channel for reduced self-heating of the CT detector. The adjustable integration time down to 51 µs allow very high frame rates. The operating range of AS5911 is specified from 0°C to 85°C.</div> | Sensor solutions | X-Ray Sensors | 265 | 51 µs | 0.29 | 1.25 mW | 26 bit | FBGA (14 x 14mm) | x-ray sensing |
| ams AS5950 CT Sensor Chip | The AS5950 is a sensor chip for 16-slice CT detectors that combines the photodiodes and the readout circuit on a single CMOS chip. This sensor solution, which includes an array of photodiodes with ultra-low dark current and a 64-channel ADC side-by-side, allows the assembly of the pixel array on three adjacent edges of the device. Two AS5950 ICs can be placed in Z-direction enabling the design of 16-slice detectors for cost optimized CT machines. <br> The total sensor dimension in Z-direction is selectable between 16 or 32 mm, enabling two modes of operation. The adaptive array concept allows either a high resolution or a large sensor size on the detector. Pixel dimensions can be customized on request. The available standard product comes with a pixel dimension of 0.98x0.98 mm². The sensor can be directly assembled on a substrate using a wire bonding process for manufacturing of a CT module. <br> Superior image quality can be achieved because the input-related noise is very low. In high-resolution mode a typical noise of 0.20 fC can be reached including the photodiode. This ultra-low noise figure is the result of the small capacitance of the photodiode, and the very low parasitic capacitance of the interconnect between the photodiode and its corresponding ADC channel. <br> The low power consumption of typ. 0.65 mW per channel reduces self-heating effects and reduces the overall cost of cooling the system. The digital data readout can be accessed via SPI interface. It is also used to configure parameters such as pixel resolution, input current range, active sensor area and enabling the calibration mode. An integrated temperature sensor enables monitoring of the junction temperature. Featuring on-chip photodiodes, the AS5950 offers a cost-optimized solution and is delivered as die on foil. <br> | Sensor solutions | X-Ray Sensors | 64 | 200 µs | 0.20 | 0.65 mW | 25 bit | die-on-foil | x-ray sensing |
| ams AS5951 CT Sensor Chip | The AS5951 is a sensor chip for 32-slice CT detectors that combines the photodiodes and the readout circuit on a single CMOS chip. This sensor solution, which includes an array of photodiodes with ultra-low dark current and a 128-channel ADC side-by-side, allows the assembly of the pixel array on three adjacent edges of the device. Two AS5951 ICs can be placed in Z-direction enabling the design of 32-slice detectors for cost optimized CT machines.<br><div><br></div><div>The AS5951 has a sensor dimension in Z-direction of 15.615 mm with a pixel dimension of 0.98x0.98 mm² in high resolution mode. In low dose mode two pixels are connected together to a 0.98x1.96 mm², this mode reduces the power consumption, as only half of the ADC channels are active. Pixel dimensions can be customized on request. The sensor can be directly assembled on a substrate using a wire bonding process for manufacturing of a CT module.<br></div><div><br></div><div>Improved low dose performance can be achieved because of superior dark current of max. 1pA due to the near zero offset voltage across the photodiode. The input-related noise is very low, in high-resolution mode a typ. noise of 0.21 fC can be reached for an input current range of 200 nA.<br></div><div><br></div><div>The max. power dissipation of 128 mW per device in high resolution mode and 67.2 mW in low power mode reduces self-heating effects and lowers the overall cost of cooling the system. An internal reference voltage and bias generator reduces the bill of material. Featuring on-chip photodiodes, the AS5951 offers a cost-optimized solution for 32-slice CT detectors.<br></div><div><br></div><div>The digital data readout can be accessed via SPI interface. It is also used to configure parameters such as mode of operation, input current range, selection of reference voltage and enabling the calibration mode. An integrated temperature sensor enables monitoring of the junction temperature. <br></div> | Sensor solutions | X-Ray Sensors | 128 | 200 µs | 0.21 | 0.82 mW | 25 bit | die-on-foil | x-ray sensing |
Featured Products
ams AS5912 CT Detector Interface
The AS5912 is an ultra-low noise, 512-channel low power current to digital converter that enables the readout of photodiodes of a CT detector with highest sensitivity. The output currents of 512 photodiodes are converted simultaneously into digital without any dead time resulting in no charge loss on the inputs. The AS5912 combines current-to-voltage integration and A/D conversion for 512-channels in one device. The ADC architecture with its low-noise integrators, coarse quantizer, sample-and-hold and fine quantizer guarantee lowest input related noise of maximum 0.29 fC (low noise mode) at an input current range of 0.5 µA. The input current range of the ADC is selectable between 0.5 µA and 1 µA.The AS5912 supports two supply concepts: a single analog and true ground supply, in both modes the photodiodes are zero biased for ultra-low dark current of the photodiode. In true ground mode, the AS5912 operates at ±1.5 V dual analog supply while in single supply mode only a single analog supply of +3.0 V is needed. The device detects automatically the chosen supply concept. No external components are required for supply decoupling. To reduce PCB area and simplify the assembly process, decoupling capacitors for supply and reference voltages are integrated in the 23 x 15 mm² FBGA package. The on-chip LDOs, reference voltages and a temperature sensor minimize the external component requirements and reduces the bill of material.Full-scale range, integration time and power mode are configurable over a SPI-compatible serial interface as well as the digital output modes of the LVDS interface. In low power mode, the power dissipation can be minimized down to 1.25 mW per channel for reduced self-heating of the CT detector. The adjustable integration time down to 51 µs allow very high frame rates.
ams AS5951 CT Sensor Chip
The AS5951 is a sensor chip for 32-slice CT detectors that combines the photodiodes and the readout circuit on a single CMOS chip. This sensor solution, which includes an array of photodiodes with ultra-low dark current and a 128-channel ADC side-by-side, allows the assembly of the pixel array on three adjacent edges of the device. Two AS5951 ICs can be placed in Z-direction enabling the design of 32-slice detectors for cost optimized CT machines.The AS5951 has a sensor dimension in Z-direction of 15.615 mm with a pixel dimension of 0.98x0.98 mm² in high resolution mode. In low dose mode two pixels are connected together to a 0.98x1.96 mm², this mode reduces the power consumption, as only half of the ADC channels are active. Pixel dimensions can be customized on request. The sensor can be directly assembled on a substrate using a wire bonding process for manufacturing of a CT module.Improved low dose performance can be achieved because of superior dark current of max. 1pA due to the near zero offset voltage across the photodiode. The input-related noise is very low, in high-resolution mode a typ. noise of 0.21 fC can be reached for an input current range of 200 nA.The max. power dissipation of 128 mW per device in high resolution mode and 67.2 mW in low power mode reduces self-heating effects and lowers the overall cost of cooling the system. An internal reference voltage and bias generator reduces the bill of material. Featuring on-chip photodiodes, the AS5951 offers a cost-optimized solution for 32-slice CT detectors.The digital data readout can be accessed via SPI interface. It is also used to configure parameters such as mode of operation, input current range, selection of reference voltage and enabling the calibration mode. An integrated temperature sensor enables monitoring of the junction temperature.
ams AS5850B Digital X-ray Flat Panel Readout IC
The AS5850B is a 16-bit, 256-channel low-noise charge-to-digital converter designed for use in digital X-ray systems. The high degree of programmability enables system performance optimization in a wide range of applications. The combination of fast speed, low noise and low power consumption maximizes the image quality and minimizes patient dose, exposure whilst improving the time to market.Each channel front-end consists of a charge sensitive amplifier (CSA) and a correlated double sampler (CDS), that removes offset and flicker noise from the signal, which is then converted to digital. A fast and reliable LVDS interface transmits the output digital data off-chip. Built-in diagnostic functionalities enable to locate the source of errors in the signal chain from the detector to the data acquisition system. Voltage references and a temperature sensor are included on the chip. An SPI interface allows easy programming of the device parameters.Four different power modes allow the user to minimize the current consumption for the chosen speed. Line times of 20, 28.5, 40 and 80 μs require as little as 3.1, 2.6, 1.6 and 1.1 mW per channel respectively. A special ADC operation mode is also available, that decreases the minimum line time to 15 μs without increasing the power consumption. Additionally, it is possible to add together the charges in pairs of adjacent channels; with this binning, the fastest achievable line time is 10 μs.