™ Peripheral Imaging Corporation 650 N. Mary Ave. Sunnyvale, California, 94085 Phone: 408-962-1913 Fax: 408-962-1998 PI0512WS 512-Pixel 50-µm-Pitch Wide Aperture Spectroscopic Photodiode Array Engineering Data Sheet Description Peripheral Imaging Corporation's WS series is family of self-scanning photodiode solid-state linear imaging arrays. These photodiode sensors employ PIC’s proprietary CMOS Image Sensing Technology to integrate the sensors into single monolithic chip. These sensors are optimally designed for applications in spectroscopy. Accordingly, these sensors contain a linear array of photodiodes with an optimized geometrical aspect ratio (50-µm aperture pitch x 2500-µm aperture width) for helping to maintain mechanical stability in spectroscopic instruments and for providing their light-capturing ability. The family of sensor consists of active photodiode arrays of different number of pixels, 256 and 512. Figure 1. Pinout configuration. PI0512WS Page 1 of 8 – July 26, 2001 The WS series devices are mounted in 22-pin ceramic side-brazed dual-in-line packages that will insert in a standard DIP socket. A diagram of the package and its pinout configuration is seen in Figure 1. Features • • • • • • • • • • High saturation capacitance (60pF ) for wide dynamic range. Wide spectral response (180-1000) for UV and IR response. PN junction photodiodes highly resistive to UV damage. Low dark current. Integration time from 0.52 ms to 0.6 seconds at room temperature. Longer integration time extended to hours by cooling. High linearity. Low power dissipation. Geometrical structure to enhance stability and registration. Standard 22-lead dual-in-line integrated-circuit package. Sensor Characteristics The Peripheral Imaging Corporation's self-scanned photodiodes are on 50-µm center-to-center spacing. Hence, their line density 20 diodes/mm and accordingly the overall die lengths of the different arrays vary with the number of photodiodes. For example, the 256-pixel array is 12.8-mm long and the 512 pixel array is 25.6-mm long. In addition, each array has four additional dummy, non-imaging photodiodes with two on each side. The height of the sensors is 2500 µm. Accordingly, these slit-like apertures make these sensors desirable for coupling to monochromators and spectrographs. Figure 2. Geometry and layout of photodiode pixels. PI0512WS Page 2 of 8 – July 26, 2001 During normal operation, the impinging photons in or near the PN photodiode junction generate free charges that are collected and stored on the junction's depletion capacitance. Since on average a certain fraction of charge is generated and collected for each impinging photon, the number of collected charges will proportionally increase with light exposures. Figure 3 shows the stored signal charge as function of light exposure at a wavelength of 575 nm. The exposure is the product of the light intensity in nW/cm2 and integration time in seconds. The charge accumulates linearly until reaching the saturation charge where the corresponding exposure is the saturation exposure. Output Charge (pC) 70 60 50 Saturation Charge 40 30 20 Saturation Exposure 10 0 0 50 100 150 200 Exposure (nJ/cm^2) Figure 3. Stored signal charge as function of exposure at a wavelength of 575 nm. Responsivity (C/J/cm^2) The responsivity is defined as ratio of saturation charge divided by saturation exposure. The measured typical responsivity of a photodiode is 3.3×10-4 C/J/cm2 at 575 nm. Figure 4 shows the predicted responsivity of the photodiodes as a function of wavelength. 5.0E-04 QE=80% 4.5E-04 4.0E-04 QE=60% 3.5E-04 3.0E-04 QE=40% 2.5E-04 2.0E-04 QE=20% 1.5E-04 1.0E-04 5.0E-05 0.0E+00 100 300 500 700 900 Wavelength (nm) Figure 4. Predicted spectral response. PI0512WS Page 3 of 8 – July 26, 2001 Note: Quantum Efficiency (QE) can be calculated by dividing the responsivity by the area of the sensor's element and multiplying the resulting ratio by the energy per photon in electron volts (eV). The dark current is typically about 1 pA at 25oC and will vary as function of temperature. The dark current will contribute dark-signal charges and these charges will increase as direct function of integration time and superimpose on the image signal charges. Self-Scanning Circuit Figure 5 shows a simplified electrically equivalent circuit diagram of the photodiode array. Every photodiode in the array is connected to a common output video line by a MOS switch. Impinging photons generate charge that is collected on each imaging photodiode when the switch is open. As the shift register sequentially closes each MOS switch, the stored charge, which is proportional in amount to the light exposure, from each corresponding photodiode is readout onto the video line. The output charge on the video line from each photodiode pixel is typically sensed by an external charge-integrating amplifier. The shift register is activated with the entry of the start pulse. This pulse propagates through each shift register stage and activates the MOS switches sequentially. When the pulse reaches the last shift register stage, the fourth and last dummy pixel is readout and end-of-scan (EOS) output is held high for one clock cycle. DUMMY4 DUMMY3 PIX512 PIX511 PIX2 PIX1 DUMMY2 DUMMY1 VDD BIAS RESET AVIDEO START CLK START CLK SHIFT REGISTER EOS EOS PI0512WS Figure 5. Simplified circuit diagram of PI0512WS photodiode array. PI0512WS Page 4 of 8 – July 26, 2001 I/O Pins Although the PI0512WS package has 22 pins as shown in Figure 1, there are only 6 functionally active I/O pins in addition to the supply and bias pins as shown in Figure 5. Table 1 defines the I/O acronyms, provides their full names and describes their functions. In essence, only two clocks, CLK and START, are required for controlling the timing of the sensor's video readout if the internal reset circuitry is not used. However, if the internal reset circuitry is used, a third clock signal, RESET, is required. The remaining I/O descriptions are for the video signal output, the end-of-scan signal, and the bias and supply voltage. These I/Os are listed with their acronym designators and functional descriptions in the following Table 1. Table 1. Symbols and functions and I/O pins. Symbol VSS VDD START CLK EOS Function and Description Ground. +5.0 Volts. Start Pulse: Input to start the line scan. Clock Pulse: Input to clock the shift register. End Of Scan: Output from the shift register to indicate the completion of one line scan. AVIDEO Active Video Line: Charge output from the photodiodes pixels. RESET Reset Control Gate: Pulsing this input will reset the video line to the reset bias. BIAS Reset Bias Supply: Input bias reference resetting the video line. PI0512WS Page 5 of 8 – July 26, 2001 Clock and Voltage Requirements Clocks requirements are relatively simple. As it was indicated in Figure 5 and Table 1, there are only three input signals that require clocked inputs. They are CLK, the clock for the shift register, START, the shift register start pulse, and RESET, the reset control gate. However, in certain applications where the internal reset circuitry is unused, RESET can be tied to ground. Figure 6. Timing diagram. Table 2 . Symbol definitions and timing specifications for timing diagram. Item Symbol Clock cycle time to Clock pulse width tw Clock duty cycle Prohibit crossing time of Start Pulse tprh Data setup time tds Data hold time tdh End Of Scan delay tdeo End Of Scan off tdee Signal delay time tsd Signal settling time tsh Min 5 1 20 0 50 100 50 Typical Max Units µs µs 50 80 % ns ns ns 300 ns 300 ns ns 500 ns The timing specifications and the symbol definition for Figure 6 are listed in Table 2. The control clock amplitudes for I/Os are compatible with the 5-Volt CMOS devices. PI0512WS Page 6 of 8 – July 26, 2001 Recommended Operating Conditions at Room Temperature Table 3 lists the recommended operational conditions. Table 3. Recommended operating conditions at room temperature. Parameters Symbol Min. Typical Max. Units Power supply VDD 4.5 5.0 5.0 Volts Input clock pulses high level 1 Vih VDD – 0.8 VDD VDD Volts Input clock pulse low level 1 Vil 0.0 0.0 0.8 Volts Video output bias levels (dark) Vbias 0.0 0.5 2.5 Volts Clock frequency 2 Fclk 100 1000 kHz Clock pulse duty cycle 20 50 80 % Integration time 3 Tint 0.52 600 ms Notes: (1) Applies to all control-clock inputs. (2) The minimum clock frequency must be consistent with the integration time as indicated in note (3). (3) Integration time is specified at room temperature such that the maximum dark current charge build up in each pixel is less than 10% of the typical saturation charge. Accordingly, it can be as short as 0.52 ms or as long as 0.6 seconds at room temperature . Longer integration times are possible by cooling the device. Package Dimensions Note: Dimensions are in inches except where millimeters (mm) are indicated. PI0512WS Page 7 of 8 – July 26, 2001 Electro-Optical Characteristics (25oC) Table 4 lists the electro-optical characteristics of PI0512WS sensor chip at 25oC. Table 4. Electro-optical characteristics. Parameters Center-to-center spacing Aperture width Pixel area Fill factor 1 Quantum efficiency 1,2 Responsivity 1,2 Nonuniformity of response 3 Saturation exposure 2 Saturation charge Average dark current 4 Spectral response peak Spectral response range 5 Symbol Min A FF QE R Esat Qsat λ 55 Typical 50 2500 1.25×10-3 76 75 3.3×10-4 2 180 60 1 600 180 – 1000 Max 5 3 Units µm µm cm2 % % C/J/cm2 +/-% nJ/cm2 pC pA nm nm Notes: (1) Fill factor, quantum efficiency, and responsivity are related by the equation R = . . . (qeλ/hc) QE FF A, where qe is the charge of an electron and hc/λ is the energy of a photon at a given wavelength. (2) At wavelength of 575 nm (yellow-green) and with no window. (3) Measured at 50% Vsat with incandescent tungsten lamp filtered with a Schott KG-1 heat-absorbing glass. (4) Max dark leakage ≤ 1.5 x average dark leakage measured with an integration period o of 500 ms at 25 C. (5) From 250-1000 nm, responsivity ≥ 20% of its peak value. ©2001 AMI Semiconductor. Printed in USA. All rights reserved. Specifications are subject to change without notice. Contents may not be reproduced in whole or in part without the express prior written permission of AMIS. Information furnished herein is believed to be accurate and reliable. However, no responsibility is assumed by AMIS for its use nor for any infringement of patents or other rights granted by implication or otherwise under any patent or patent rights of AMIS. PI0512WS Page 8 of 8 – July 26, 2001