(R) (R) ADCDS-1403 14-Bit, 3 Megapixels/Second Imaging Signal Processor PRELIMINARY PRODUCT DATA FEATURES * * * * * * * * * * 14-bit resolution 3MPPS throughput rate (14-bits) Functionally complete Very low noise Excellent Signal-to-Noise ratio Edge triggered Small, 40-pin, TDIP package Low power, 500mW typical Low cost Programmable Analog Bandwidth INPUT/OUTPUT CONNECTIONS PIN FUNCTION PIN FUNCTION 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 FINE GAIN ADJUST OFFSET ADJUST DIRECT INPUT INVERTING INPUT NON-INVERTING INPUT +2.4V REF. OUTPUT ANALOG GROUND NO CONNECT NO CONNECT BIT 14 (LSB) BIT 13 BIT 12 BIT 11 BIT 10 BIT 9 BIT 8 BIT 7 BIT 6 BIT 5 BIT 4 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 NO CONNECT +12V -5VA ANALOG GROUND +5VA ANALOG GROUND +5VD DIGITAL GROUND DIGITAL GROUND A1 A NO CONNECT NO CONNECT DATA VALID REFERENCE HOLD START CONVERT OUT-OF-RANGE BIT 1 (MSB) BIT 2 BIT 3 GENERAL DESCRIPTION The ADCDS-1403 is an application-specific video signal processor designed for electronic-imaging applications that employ CCD's (charge coupled devices) as their photodetector. The ADCDS-1403 incorporates a "user configurable" input amplifier, a CDS (correlated double sampler) and a sampling A/ D converter in a single package, providing the user with a complete, high performance, low-cost, low-power, integrated solution. The key to the ADCDS-1403's performance is a unique, highspeed, high-accuracy CDS circuit, which eliminates the effects of residual charge, charge injection and "kT/C" noise on the CCD's output floating capacitor, producing a "valid video" output signal. The ADCDS-1403 digitizes this resultant "valid video" signal using a high-speed, low-noise sampling A/D converter. The ADCDS-1403 requires only the rising edge of start convert pulse to initiate its conversion process. Additional features of the ADCDS-1403 include gain adjust, offset adjust, precision +2.4V reference, and a programmable analog bandwidth function. +12VA 75 +5VA -5VA 39 38 +5VD 36 34 523 INVERTING INPUT 4 25 START CONVERT 1 FINE GAIN ADJUST INPUT AMPLIFIER 0.01F DIRECT INPUT 3 NON-INVERTING INPUT 5 5K CORRELATED DOUBLE SAMPLER 23 BIT 1 (MSB) SAMPLING A/D 10 BIT 14 (LSB) OFFSET ADJUST 2 REFERENCE HOLD 26 TIMING AND CONTROL 24 OUT-OF-RANGE 6 32, 33 DIGITAL GROUND 27 DATA VALID 30 31 AO A1 +2.4V REFERENCE OUTPUT 7, 35, 37 ANALOG GROUND Figure 1. ADCDS-1403 Functional Block Diagram DATEL, Inc., Mansfield, MA 02048 (USA) * Tel: (508) 339-3000, (800) 233-2765 Fax: (508) 339-6356 * Email: sales@datel.com * Internet: www.datel.com (R) (R) ADCDS-1403 ABSOLUTE MAXIMUM RATINGS PARAMETERS MIN. TYP. MAX. UNITS +12V Supply (Pin 32) -5V Supply (Pin 31) +5V Supply (Pin 28, 29) Digital Input (Pin 23, 24) Analog Input (Pin 3,4,5) Lead Temperature (10 seconds) 0 -0.3 0 -0.3 -5 -- -- -- -- -- -- -- +14 +6.5 -6.5 Vdd+0.3V +5 300 Volts Volts Volts Volts Volts C DYNAMIC PERFORMANCE Reference Hold Aquisition Time Droop @ +25C @ -55 to +125C Peak Harmonic (SFDR) (CDD-IN, input on pin (3) Input @ 98 KHZ) @ +25 C @ 0 to +70C @ -55 to +125C Peak Harmonic (SFDR) (Input on pin (5) Input @ 98 KHZ) @ +25 C @ 0 to +70C @ -55 to +125C Total Harmonic Distortion (CDD-IN, input on pin (3) Input @ 98 KHZ) @ +25 C @ 0 to +70C @ -55 to +125C (Input on pin (5) Input @ 98 KHZ) @ +25 C @ 0 to +70C @ -55 to +125C Signal-to-Noise Ratio Without Distortion (CDD-IN, input on pin (3) Input @ 98 KHZ) @ +25 C @ 0 to +70C @ -55 to +125C (Input on pin (5) Input @ 98 KHZ) @ +25 C @ 0 to +70C @ -55 to +125C Signal-to-Noise Ratio With Distortion (CDD-IN, input on pin (3) Input @ 98 KHZ) @ +25 C @ 0 to +70C @ -55 to +125C (Input on pin (5) Input @ 98 KHZ) @ +25 C @ 0 to +70C @ -55 to +125C FUNCTIONAL SPECIFICATIONS The following specifications apply over the operating temperature range, under the following conditions: Vcc=+12V, +Vdd=+5V, Vee=-5V, fin=98KHz, sample rate=3MHz. ANALOG INPUT MIN. TYP. MAX. UNITS Input Voltage Range (externally configurable) Input Resistance Input Capacitance 0.350 -- -- 2.8 5000 10 -- -- -- Volts p-p Ohm pF DIGITAL INPUTS Logic Levels Logic 1 Logic 0 Logic Loading Logic 1 Logic 0 +3.5 -- -- -- -- +.80 Volts Volts -- -- -- -- +10 -10 uA uA +2.4 +4.5 -- -- -- -- -- -- -- -- +0.4 +0.1 Volts Volts Volts Volts 2.35 2.35 2.35 -- 2.4 2.4 2.4 1.0 2.45 2.45 2.45 -- Volts Volts Volts mA DIGITAL OUTPUTS Logic Levels Logic 1 (IOH = .5ma) Logic 1 (IOH = 50a) Logic 0 (IOL = 1.6ma) Logic 0 (IOL = 50ua) Internal Reference Voltage (Fine gain adjust pin (1) grounded) +25C 0 to 70C -55 to +125C External Current STATIC PERFORMANCE Differential Nonlinearity (Histogram, 98kHz) +25C 0 to 70C -55 to +125C Integral Nonlinearity +25C 0 to 70C -55 to +125C Guaranteed No Missing Codes 0 to 70C -55 to +125C DC Noise +25C 0 to 70C -55 to +125C Offset Error +25C 0 to 70C -55 to +125C Gain Error +25C 0 to 70C -55 to +125C -0.90 -0.90 -1.0 0.5 0.5 0.6 +.90 +.90 +1.0 LSB LSB LSB -- -- -- 2.5 2.5 2.5 -- -- -- LSB LSB LSB 14 14 -- -- -- -- LSB LSB -- -- -- 1.0 1.0 1.25 2.0 2.0 3.0 LSB LSB LSB -- -- -- 0.6 0.6 0.7 1.07 1.25 1.35 %FSR %FSR %FSR -- -- -- 1.43 1.35 1.35 2.8 2.8 2.8 %FSR %FSR %FSR 100 -- -- ns -- -- 25 100 -- -- mV/us mV/us -- -- -- -76 -76 -74 -72 -72 -72 dB dB dB -- -- -- -76 -76 -74 -72 -72 -72 dB dB dB -- -- -- -75 -75 -74 -72 -72 -69 dB dB dB -- -- -- -76 -76 -74 -72 -72 -69 dB dB dB 73 72 68 75 75 75 -- -- -- dB dB dB 73 72 68 75 75 75 -- -- -- dB dB dB 69 69 67 71 71 70 -- -- -- dB dB dB 70 70 67 71 71 70 -- -- -- dB dB dB 3 -- 20 -- 200 150 -- -- -- MHz nsec nsec MIN. TYP. MAX. UNITS +11.4 +4.75 -4.75 +12.0 +5.0 -5.0 +12.6 +5.25 -5.25 Volts Volts Volts -- +13 +16 mA SIGNAL TIMING Conversion Rate -55 to +125C Conversion Time Start Convert Pulse Width POWER REQUIREMENTS Power Supply Range +12V Supply +5V Supply -5V Supply Power Supply Current +12V Supply 2 (R) (R) ADCDS-1403 POWER REQUIREMENTS Power Supply Current +5V Supply -5V Supply Power Dissipation Power Supply Rejection (5%) @ +25C MIN. TYP. MAX. Direct Mode (AC Coupled) UNITS -- -140 -- +40 -27 0.50 +46 -35 0.60 mA mA Watts -- -- 0.007 %FSR/%V 0 -55 -65 -- -- -- +70 +125 +150 C C C This is the most common input configuration as it allows the ADCDS-1403 to interface directly to the output of the CCD with a minimum amount of analog "front-end" circuitry. This mode of operation is used with full-scale video input signals from 0.350Vp-p to 2.8Vp-p. Figure 2a. describes the typical configuration for applications using a video input signal with a maximum amplitude of 0.350Vp-p. The coarse gain of the input amplifier is determined from the following equation: VOUT = 2.8Vp-p = VIN*(1+(523/75)), with all internal resistors having a 1% tolerance. Additional fine gain adjustment can be accomplished using the Fine Gain Adjust (pin 1). ENVIRONMENTAL Operating Temperature Range -MC -MC Storage Temperature Package Type Weight Figure 2b. describes the typical configuration for applications using a video input signal with an amplitude greater than 0.350Vp-p and less than 2.8Vp-p. Using a single external series resistor (see Fig. 4.), the coarse gain of the ADCDS1403 can be set, with additional fine gain adjustments being made using the Fine Gain Adjust function (pin 1). The coarse gain of the input amplifier can be determined from the following equation: VOUT = 2.8Vp-p = VIN*(1+(523/(75+Rext))), with all internal resistors having a 1% tolerance. 40-pin, TDIP 16.10 grams TECHNICAL NOTES 1. Obtaining fully specified performance from the ADCDS-1403 requires careful attention to pc-card layout and power supply decoupling. The device's analog and digital grounds are connected to each other internally. Depending on the level of digital switching noise in the overall CCD system, the performance of the ADCDS-1403 may be improved by connecting all ground pins (7,32,33,35, 37) to a large analog ground plane beneath the package. The use of a single +5V analog supply for both the +5VA (pin 36) and +5VD (pin 34) may also be beneficial. 2. Bypass all power supplies to ground with a 4.7f tantalum capacitor in parallel with a 0.1f ceramic capacitor. Locate the capacitors as close to the package as possible. VIN NO CONNECT 3. If using the suggested offset and gain adjust circuits (Fig. 3 & 5), place them as close to the ADCDS-1403's package as possible. 4 75 3 0.01F 523 VOUT = 2.8Vp-p 5 5k Figure 2a. ADCDS-1403 Modes of Operation The input amplifier stage of the ADCDS-1403 provides the designer with a tremendous amount of flexibility. The architecture of the ADCDS-1403 allows its input-amplifier to be configured in any of the following configurations: Rext * Direct Mode (AC coupled) * Non-Inverting Mode * Inverting Mode VIN NO CONNECT 4 75 3 0.01F 523 VOUT = 2.8Vp-p 5 5k When applying inputs which are less than 2.8Vp-p, a coarse gain adjustment (applying an external resistor to pin 4) must be performed to ensure that the full scale video input signal (saturated signal) produces a 2.8Vp-p signal at the inputamplifier's output (Vout). Figure 2b. In all three modes of operation, the video portion of the signal at the CDS input (i.e. input-amplifier's Vout) must be more negative than its associated reference level and Vout should not exceed 2.8V DC. Rext NO CONNECT The ADCDS-1403 achieves it specified accuracies without the need for external calibration. If required, the device's small initial offset and gain errors can be reduced to zero using the FINE GAIN ADJUST (pin1) and OFFSET ADJUST (pin 2) features. VIN 4 75 3 0.01F 523 VOUT = 2.8Vp-p 5 5k Figure 2c. 3 (R) (R) ADCDS-1403 Non-Inverting Mode Inverting Mode The non-inverting mode of the ADCDS-1403 allows the designer to either attenuate or add non-inverting gain to the video input signal. This configuration also allows bypassing the ADCDS1403's internal coupling capacitor, allowing the user to provide an external capacitor of appropriate value. The inverting mode of operation can be used in applications where the analog input to the ADCDS-1403 has a video input signal whose amplitude is more positive than its associated reference level. The ADCDS-1403's correlated double sampler (i.e. input amplifier's VOUT) requires that the video signal's amplitude be more negative than its reference level at all times (see timing diagram for details). Using the ADCDS-1403 in the inverting mode allows the designer to perform an additional signal inversion to correct for any analog "front end" pre-processing that may have occurred prior to the ADCDS-1403. Figure 2c. describes the typical configuration for applications using video input signals with amplitudes greater than 0.350Vp-p and less than 2.8Vp-p (with common mode limit of 2.5V DC). Using a single external series resistor (see Fig. 4.), the coarse gain of the ADCDS-1403 can be set with additional fine gain adjustments being made using the Fine Gain Adjust function (pin 1). The coarse gain of the circuit can be determined from the following equation: VOUT = 2.8Vp-p = VIN*(1+(523/(75+Rext))), with all internal resistors having a 1% tolerance. Figure 2e. describes the typical configuration for applications using a video input signal with a maximum amplitude of 0.400Vp-p. Additional fine gain adjustments can be made using the Fine Gain Adjust function (pin 1). The coarse gain of this circuit can be determined from the following equation: VOUT = 2.8Vp-p = -VIN*(523/75), with all internal resistors having a 1% tolerance. Figure 2d. describes the typical configuration for applications using a video input signal whose amplitude is greater than 2.8Vp-p. Using a single external series resistor (Rext 1) in conjunction with the internal 5K (1%) resistor to ground, an attenuation of the input signal can be achieved. Additional fine gain adjustments being made using the Fine Gain Adjust function (pin 1). The coarse gain of this circuit can be determined from the following equation: VOUT = 2.8Vp-p = [VIN*(5000/(Rext1+5000))]* [1+(523/(75+Rext2))], with all internal resistors having a 1% tolerance. Rext2 4 75 3 0.01F 523 VOUT = 2.8Vp-p NO CONNECT Rext1 Figure 2f. describes the typical configuration used in applications needing to invert video input signals whose amplitude is greater than 0.400Vp-p. Using a single external series resistor (see Fig. 4.), the initial gain of the ADCDS-1403 can be set, with additional fine gain adjustments being made using the Fine Gain Adjust function (pin 1). The coarse gain of this circuit can be determined from the following equation: VOUT = 2.8Vp-p = -VIN*(523/75+Rext), with all internal resistors having a 1% tolerance. ADCDS-1403 5 VIN 5k +5V Figure 2d. -VIN 4 75 3 0.01f 20K 523 -5V Figure 3. Offset Adjustment Circuit 5 5k Figure 2e. Rext Offset Adjust 2 VOUT = 2.8Vp-p NO CONNECT -VIN External Series Resistor 4 75 3 0.01f 523 VOUT = 2.8Vp-p NO CONNECT 5 5k Figure 2f. 4 (R) (R) ADCDS-1403 Offset Adjustment ADCDS-1403 Manual offset adjustment for the ADCDS-1403 can be accomplished using the adjustment circuit shown in Figure 3. A software controlled D/A converter can be substituted for the 20K potentiometer. The offset adjustment feature allows the user to adjust the Offset/Dark Current level of the ADCDS1403 until the output bits are 00 0000 0000 0000 and the LSB flickers between 0 and 1. Offset adjust should be performed before gain adjust to avoid interaction. The ADCDS-1403's offset adjustment is dependent on the value of the external series resistor used in the offset adjust circuit (Fig. 3). The Offset Adjustment graph (Fig. 6) illustrates the typical relationship between the external series resistor value and its offset adjustment capability utilizing 5V supplies. +5V 20K -5V Figure 5. Fine Gain Adjustment Circuit Offset Adjustment Sensitivity External Series Resistor vs. Output Variation (LSB's) Offset Adjustment vs. External Series Resistor Output Variation (LSB's) 100 1000 100 Peak-Peak variation at potentiometer 10 100mV 1 10mV 0.1 1mV 0.01 0 0 5k 10k 15k 20k 25k 30k 35k 40k 45k 50k 55k 5K 10K 15K 20K 25K 30K 35K 40K 45K 50K 55K 60K 60k External Series Resistor Value (Ohms) External Series Resistor (Ohm's) Figure 7. Offset Adjustment Sensitivity Figure 6. Offset Adjustment vs. External Series Resistor Coarse Gain Adjustment Plot External Gain Resistor vs. Full Scale Video Input External Gain Resistor (Ohms) LSB's of Adjustment 10000 10 Fine Gain Adjust 1 10000 Direct Mode & Non-Inverting Mode 1000 Inverting Mode 100 10 0.25 0 . 5 0 .7 5 1 1 .2 5 1 .5 1 .7 5 2 2 .2 5 2 .5 Full Scale Video Signal (Volts) Figure 4. Coarse Gain Adjustment Plot 5 2 .7 5 3 (R) (R) ADCDS-1403 Offset Adjustment Sensitivity Fine gain adjustment for the ADCDS-1403 is accomplished using the adjustment circuit shown below (Fig. 5). A software controlled D/A converter can be substituted for the 20K potentiometer. The fine gain adjust circuit ensures that the video input signal (saturated signal) will be properly scaled to obtain the desired Full Scale digital output of 11 1111 1111 1111, with the LSB flickering between 0 and 1. Fine gain adjust should be performed following the offset adjust to avoid interaction. The fine gain adjust provides 256 codes of adjust when 5V supplies are used for the Fine Gain Adjust Circuit. It should be noted that with increasing amounts of offset adjustment (smaller values of external series resistors), the ADCDS-1403 becomes more susceptible to power supply noise or voltage variations seen at the wiper of the offset potentiometer. For Example: External 50K resistor: 1. 10mV of noise or voltage variation at the potentiometer will produce 0.25LSB's of output variation. 2. 100mV of noise or voltage variation at the potentiometer will produce 2.5LSB's of output variation. Out-of-Range Indicator The ADCDS-1403 provides a digital Out-of-Range output signal (pin 24) for situations when the video input signal (saturated signal) is beyond the input range of the internal A/D converter. The digital output bits and the Out-of-Range signal correspond to a particular sampled video input voltage, with both of these signals having a common pipeline delay. The Offset Adjustment Sensitivity graph (Fig. 7) illustrates the offset adjustment sensitivity over a wide range of external resistor and noise values. If a large offset voltage is required, it is recommended that a very low noise external reference be used in the offset adjust circuit in place of power supplies. The ADCDS-1403's +2.4V reference output could be configured to provide the reference voltage for this type of application. Using the circuit described in Figure 8., both overrange and underrange conditions can be detected (see Table 1). When combined with a D/A converter, digital detection and correction can be performed for both the gain and offset errors. Fine Gain Adjustment Fine gain adjustment (Pin 1) is provided to compensate for the tolerance of the external coarse gain resistor (Rext) and/or the unavailability of exact coarse gain resistor (Rext) values. Note, the fine gain adjustment will not change the expected input amplifier's full scale VOUT (2.8Vp-p.) Instead, the gain of the ADCDS-1403's internal A/D is adjusted allowing the actual input amplifier's full scale VOUT to produce an output code of all ones (11 1111 1111 1111). MSB "OVERRANGE" OUT-OF-RANGE "UNDERRANGE" Figure 8. Overrange/ Underrange Circuit Table 1. Out-of-Range Conditions OUT-OF-RANGE 0 0 1 1 MSB OVERRANGE UNDERRANGE 0 1 0 1 0 0 0 1 0 0 1 0 6 INPUT SIGNAL In Range In Range Underrrange Overrange (R) (R) ADCDS-1403 Output Coding The ADCDS-1403's output coding is Straight Binary as indicated in Table 2. The table shows the relationship between the output data coding and the difference between the reference signal voltage and its corresponding video signal voltage. (These voltages are referred to the output of the ADCDS-1403's input amplifier's VOUT). be forced to use the full analog bandwidth at the possible expense of noise performance. The ADCDS-1403 avoids this situation by offering a fully programmable analog bandwidth function. The ADCDS-1403 allows the user to "bandwidth limit" the input stage in order to realize the highest level of noise performance for the application being considered. Table 3. describes how to select the appropriate reference hold "aquisition time" and CDS output "settling time" needed for a particular application. Each of the selections listed in Table 3. have been optimized to provide only enough analog bandwidth to acquire a full scale input step, to 14-bit accuracy, in a single conversion. Increasing the analog bandwidth (using a faster settling and acquisition time) would only serve to potentially increase the amount of noise at the ADCDS-1403's output. The ADCDS1403 uses a two bit digital word to select four different analog bandwidths for the ADCDS-1403's input stage (See Table 3. for details). Programmable Analog Bandwidth Function When interfacing to CCD arrays with very high-speed "readout" rates, the ADCDS-1403's input stage must have sufficient analog bandwidth to accurately reproduce the output signals of the CCD array. The amount of analog bandwidth determines how quickly and accurately the "Reference Hold" and the "CDS output" signals will settle. If only a single analog bandwidth was offered, the ADCDS-1403's bandwidth would be set to acquire and digitize CCD output signals to 14-bit accuracy, at maximum conversion rate of 3MHz (333ns see Figure 11. for details). Applications not requiring the maximum conversion rate would Table 2. Output Coding INPUT AMPLIFIER VOUT, (VOLTS P-P) Video Signal-Reference Signal Video Signal-Reference Signal Notes: > -2.80000 -2.80000 -2.10000 -1.40000 -0.70000 -0.35000 -0.000171 0 <0 SCALE DIGITAL OUTPUT >Full Scale -1LSB Full Scale -1LSB 3/4FS 1/2FS 1/4FS 1/8FS 1 LSB 0 <0 11 1111 1111 1111 11 1111 1111 1111 11 0000 0000 0000 10 0000 0000 0000 01 0000 0000 0000 00 1000 0000 0000 00 0000 0000 0001 00 0000 0000 0000 00 0000 0000 0000 OUT-OF-RANGE 1 0 0 0 0 0 0 0 1 Input Amplifier VOUT = (Video Signal - Reference Level) The video portion of the differential signal (input-amplifier's VOUT) must be more negative than its associated reference level and VOUT should not exceed 2.8V DC. Table 3. Programmable Analog Bandwidth REFERENCE HOLD "AQUISITION TIME" CDS OUTPUT "SETTLING TIME" A0 (Pin 30) A1 (Pin 31) ADCDS-1403 MAXIMUM CONVERSION RATE 100ns 120ns 0 0 3MHz 200ns 250ns 1 0 2MHz 450ns 500ns 0 1 1MHz 600ns 1000ns 1 1 0.5MHz Note: See Figure 11. for timing details 7 (R) (R) ADCDS-1403 Timing sampler produces a "CDS Output" signal (see figure 11.) which is the difference between the "held" reference level and its associated video level. When the "CDS Output" signal has settled to the desired accuracy (user defined), the A/D conversion process can be initiated with the rising edge of a single start convert (Pin 25) signal. The ADCDS-1403 requires two independently operated signals to accurately digitize the analog output signal from the CCD array. * Reference Hold (pin 26) * Start Convert (pin 25) Once the A/D conversion has been initiated, Reference Hold (Pin 26) can be placed back into the "Acquisition" mode in order to begin aquiring the next reference level. For optimal performance the ADCDS-1403's internal sample-hold should be placed back into the "Aquisition" mode (Reference Hold to logic "0") during the CCD's "Reference Quiet Time" ("Reference Quiet Time" is defined as the period when the CCD's reference signal has settled from all switching transients to the desired accuracy (see Figure 10.)). Placing the sample-hold back into the "aquisition" mode during the "Reference Quiet Time" prevents the ADCDS-1403's internal amplifiers from unecessarily tracking (reproducing) the large switching transients that occur during the CCD's reset to reference transition. The "Reference Hold" signal controls the operation of an internal sample-hold circuit. A logic "1" places the sample-hold into the hold mode, capturing the value of the CCD's reference signal. The Reference Hold Signal allows the user to control the exact moment when the sample-hold is placed into the "hold" mode. For optimal performance the sample-hold should be placed into the "hold" mode once the reference signal has fully settled from all switching transients to the desired accuracy (user defined). Once the reference signal has been "held" and the video portion of the CCD's analog output signal appears at the ADCDS-1403's input, the ADCDS-1403's correlated double +12V 4.7F + +5VD 4.7F + -5VA 4.7F + +5VA 4.7F + 0.1F 0.1F 0.1F 0.1F 39 +5V 1 20K +5V 20K -5V 38 36 23 BIT 1 (MSB) FINE GAIN ADJUST -5V External Series Resistor 36 22 BIT 2 ADCDS-1403 2 21 BIT 3 20 BIT 4 19 BIT 5 OFFSET ADJUST 18 BIT 6 3 17 BIT 7 DIRECT INPUT 16 BIT 8 4 INVERTING INPUT 15 BIT 9 14 BIT 10 5 13 BIT 11 NON-INVERTING INPUT 12 BIT 12 30 A 11 BIT 13 10 BIT 14 (LSB) 31 A1 25 START CONVERT 6 26 +2.4V REFERENCE OUT 24 OUT-OF-RANGE REF. HOLD 27 DATA VALID 7, 35, 37 ANALOG GROUND 32, 33 DIGITAL GROUND Figure 9. ADCDS-1403 Connection Diagram 8 (R) (R) ADCDS-1403 Reset Reference "Quiet Time" Reference CCD OUTPUT Video 100NS MIN. HOLD REFERENCE HOLD Acquisition Time Acquisition mode during Reference "Quiet Time" Note: For optimal performance (Fastest Acquisition Time), the ADCDS-1403 should be placed into the Acquisition mode (Reference Hold to logic "0") during the CCD output's Reference "Quiet Time". Reference "Quiet Time" is defined as the period when the reference signal's switching transients have settled to an acceptable (user defined) accuracy. Figure 10. Reference Hold Timing Reset N Reset N+1 Ref NN Ref. Reset N+2 Reset N+3 Ref. N+1 CCD OUTPUT Ref. N+2 Reset N+4 Ref. N+3 Video VideoN+2 N+1 Video N+1 Ref. N+4 Video VideoN+3 N+1 Video N Acquisition Time 133ns min. 333ns min 100ns min. Hold REFERENCE HOLD IN 120ns min min.settling settlingline time Full Scale Step N CDS OUTPUT N+2 N+1 N+3 150ns typ. min N N+1 N+2 N+3 START CONVERT DATA VALID 30ns min., 50ns max. Invalid data DATA OUTPUT DATA N-4 VALID min 20ns max DATA N-3 VALID DATA N-2 VALID DATA N-1 VALID DATA N VALID Note: As described in Figure 10, the 60ns min. is dependant on the quality of the CCD's Reference when the ADCDS-1403 is switched back into the track mode Figure 11. ADCDS-1403 Timing Diagram 9 (R) (R) ADCDS-1403 MECHANICAL DIMENSIONS INCHES (mm) 40 21 1 20 Dimension Tolerances (unless otherwise indicated): 2 place decimal (.XX) 0.010 (0.254) 3 place decimal (.XXX) 0.005 (0.127) 0.100 TYP. (2.540) 1.900 0.008 (48.260) 0.900 0.010 (22.86) ORDERING INFORMATION MODEL OPERATING TEMPERATURE RANGE 40-PIN PACKAGE 0 to 70C -55 to 125C TDIP TDIP ADCDS-1403MC ADCDS-1403MM (R) (R) ISO 9001 R E G I S T E R E D DS-332 DATEL, Inc. 11 Cabot Boulevard, Mansfield, MA 02048-1151 Tel: (508) 339-3000 (800) 233-2765 Fax: (508) 339-6356 Internet: www.datel.com Email: sales@datel.com Data sheet fax back: (508) 261-2857 1/99 DATEL (UK) LTD. Tadley, England Tel: (01256)-880444 DATEL S.A.R.L. Montigny Le Bretonneux, France Tel: 01-34-60-01-01 DATEL GmbH Munchen, Germany Tel: 89-544334-0 DATEL KK Tokyo, Japan Tel: 3-3779-1031, Osaka Tel: 6-354-2025 DATEL makes no representation that the use of its products in the circuits described herein, or the use of other technical information contained herein, will not infringe upon existing or future patent rights. The descriptions contained herein do not imply the granting of licenses to make, use, or sell equipment constructed in accordance therewith. Specifications are subject to change without notice. The DATEL logo is a registered DATEL, Inc. trademark.