GR16™ Technical Manual
Transcription
GR16™ Technical Manual
GR16™ 10 M SPS, 16-bit Analog Signal Digitizer up to 8MB FIFO Technical Manual 1950 5th Street, Davis, CA 95616, USA Tel: 530-758-0180 Fax: 530-758-0181 Email: [email protected] web site: www.tern.com COPYRIGHT GR16, EL, Grabber, and A-Engine are trademarks of TERN, Inc. Am188ES and Am186ES are trademarks of Advanced Micro Devices, Inc. Version 2.00 October 7, 2010 No part of this document may be copied or reproduced in any form or by any means without the prior written consent of TERN, Inc. © 2010 1950 5 Street, Davis, CA 95616, USA Tel: 530-758-0180 Fax: 530-758-0181 th Email: sales@ tern.com Web site: www.tern.com Important Notice TERN is developing complex, high technology integration systems. These systems are integrated with software and hardware that are not 100% defect free. TERN products are not designed, intended, authorized, or warranted to be suitable for use in life-support applications, devices, or systems, or in other critical applications. TERN and the Buyer agree that TERN will not be liable for incidental or consequential damages arising from the use of TERN products. It is the Buyer's responsibility to protect life and property against incidental failure. TERN reserves the right to make changes and improvements to its products without providing notice. `GR16™ 1.1 Functional Description The GR16™ is an inexpensive high speed (up to 10M samples per second), 16-bit analog signal digitizer, designed to be driven by a host TERN 16-bit controller, such as 586-Engine, AE86, or EE. The GR16™ supports a 16-bit Delta-Sigma ADC (ADS1610). With its outstanding high-speed performance, it is well-suited for demanding applications in data acquisition, scientific instruments, test equipment and communications. The GR16™ is designed as an expansion board, measuring 2.3 by 3.6 inches, for TERN 16-bit controllers such as A-Engine86, 586-Drive, EE, and FN. The GR16™ interfaces to TERN host controller via 20x2 pins at J1, and 5x2 pins at J2. 1.2 ADS1610 16-Bit, 10 MSPS Analog-to-Digital Converter The ADS1610 is a high-speed, high-precision, delta-sigma analog-to-digital converter (ADC) with 16-bit resolution. Inputs INP (H00.8) and INN (H00.6) are directly routed to the differential inputs of the ADS1610 without buffer circuits. The GR16™ also has two buffered inputs, A(H0.3) and A+ (H0.5). A- and A+ are routed to INN and INP via 10 Ohm resistors. Analog input signals must be able to handle the load presented by the switching capacitors within ADS1610. The GR16™ configures the ADS1610 with VREF = 3V (VREFN = 1V and VREFP = 4V). The 16-bit ADC data format is in binary two's complement. With VREFN = 1V and VREFP = 4V, the resulting input reference VREF = (4V - 1V) = 3V. In this case, ADC outputs are: • When INP > INN, the ADC outputs 0-0x7FFF • When INP < INN, the ADC outputs 0x8000-0xFFFF. • When INP – INN = 3V, the ADC outputs 0x7FFF. • When INN – INP = 3V, the ADC outputs 0x8000. • When INN = INP, the ADC outputs 0 or 0xFFFF. To achieve the highest analog performance, the recommended differential analog input voltage range is 3V x 0.891 = 2.67V. The absolute input voltage with respect to GND, on either INN or INP pin, must be within VREFN = 1V to VREFP = 4V range. Recommended circuit designs are available when using single-ended or differential op amps, respectively. See ADS1610 data sheet for details (www.ti.com). The GR16™ has an array of through-hole pads (H0, H00, H01) to allow installing user custom analog signal conditioning circuits. 1 `GR16™ 1.3 ADC Sampling Modes Three operation modes are available: ADC-read, ADC-FIFO, and FIFO-read. Figure 1.1 show the various sampling modes. FIFO-Read TERN HOST CPU 8MB FIFO ADC-Read ADC-FIFO 16-bit ADC ADS1610 Analog Input Figure 1.1 ADC Sampling Modes In ADC-read mode, application software running on the host can read the 16-bit ADC data at any time. Sampling rate would be limited to CPU and application processing speed. In ADC-FIFO mode, the GR16 can sample at far faster speeds (up to 10M samples per second). This data is recorded into the on-board FIFO SRAM. The ADC-FIFO operation is done entirely in hardware, without using any host CPU time. Finally, the system can be set to FIFO-read mode. The host CPU can then read as much FIFO data as desired via I/O or DMA access. 2 `GR16™ 1.4 ADC Sampling Frequency The ADC sampling clock can be driven by on-board clock oscillator, as default, or an external clock. With a 60MHz on-board oscillator, the sample rate is 10M samples per second maximum. User can control the sampling rate by using an external clock, or selecting different dividers using onboard jumpers (H1). The default setting for H1 is H1.7 = H1.8 which is CLK/6 or 10MHz sample rate. In order to change the default setting, the trace on H1 must be cut before wiring a new jumper. Figure 1.2 shows the H1 header and default trace jumper on the back of the GR16™. Table 1.1 the various sample rates for each H1 setting. H1 Figure 1.2 Frequency Divisor Jumper H1 Jumper Pins Clock Divisor Sample Rate for 60 MHz Oscillator H1.8 (RDY) = H1.7 (CKI) * DEFAULT * CLK / 6 10 MHz H1.10 (CK1) = H1.7 (CKI) CLK / 12 5 MHz H1.9 (CK2) = H1.7 (CKI) CLK / 24 2.5 MHz H1.6 (CK3) = H1.7 (CKI) CLK / 48 1.25 MHz H1.5 (CK4) = H1.7 (CKI) CLK / 96 625 kHz Table 1.1 H1 Jumper Settings 3 `GR16™ 1.5 ADC-FIFO Operation The ADC-FIFO operation runs when signals SA=0 and TR is active*. The ADC-FIFO operation will stop immediately when SA=1. Setting AST low causes the FIFO counter to reset. When AST=1, SA=0 and TR is active* the GR16™ continues filling up the FIFO with ADC readings until the selected recording length is reached forcing SA high (SA=1). The record length of the FIFO can be configured via jumper block H3. Available data lengths include 8MB (H3.4 = H3.3), 4MB (H3.4 = H3.2), or 512KB (H3.4 = H3.6). The hardware trigger signal (TR) is routed to header locations H2.7 and H1.2. By default H2.7 and H2.8 are jumpered (H2.7=H2.8=GND) forcing TR=0*. It is important that the external hardware trigger signal (TR) must stay active while the GR16™ is recording ADC readings. The FIFO will retain recorded data until it’s powered-off or a new ADC-FIFO operation is initiated. To read data from the FIFO, reset the counter by bringing AST low then high, then read from the FIFO. Every FIFO-read increments FIFO address. 1.6 GR16™ Stacks Multiple GR16™ units can be stacked via pass through sockets on J1 and J2. H2 pin 10=/PCS is the host I/O chip select. While H2.10=H2.9, as default, the Host controller J1.19 is the base I/O chip select. For each /PCS setting, there are 4 GAL chips available: GRAB1600, GRAB1640, GRAB1680, and GRAB16C0. Base I/O address are 0x00, 0x40, 0x80, and 0xC0 for these 4 GALs. Stacked GR16™ units can share a common external CK and SYNC signal on H1 header. With the CK inputs running, pulse the common shared SYNC line for the units to synchronize simultaneous conversions. Be aware that CK and SYNC signals are directly routed to ADS1610, with a voltage range of 0V-3.3V. Over voltage will damage ADS1610 ADC. 1.7 GR16-LM™ Version GR16-LM version uses a different GAL set (GR16-00, GR16-40, GR16-80, and GR16-C0) that have an active high trigger TR. This version operates when TR=1. By using an active high trigger, the SA output from one GR16 can trigger the TR signal of another GR16 allowing uninterrupted analog acquisition between GR16s. By default, H2.7 (TR) is not jumpered to GND at H2.8 on the GR16-LM version. *The original version of GR16 uses an active low (TR=0) trigger. The GR16-LM version uses a different GAL that has an active high trigger. This version operates when TR=1. GR16-LM versions can be identified by the GAL labels: GR16-00, GR16-40, GR16-80, and GR16-C0. 4 `GR16™ 1.8 GR16 Photos Figure 1.3 Front view of a EL controller with 4 GR16s. Figure 1.4 Back view of an EL controller with 4 GR16s. 5 `GR16™ Figure 1.5 Side view of a EL controller with 4 GR16s. Figure 1.6 UD with GR16TM 6 `GR16™ Figure 1.7 E-Engine with VE232 stacked on five GR16s powered by 9-30V Figure 1.8 E-Engine with stacked on five GR16s powered by external 5V 7 `GR16™ 1.9 Features • 2.3 x 3.6 x 0.5 inches • 200 mA at 5V DC power per GR16 • High-Speed Delta-Sigma ADC (ADS1610) • User Programmable Sample Rate, up to 10M SPS • On-Chip Digital Filter Simplifies Anti-Alias • User configurable FIFO data size, up to 8MB. • Stackable multi units sharing Sync, and Trigger. • On-board oscillator or external host clock. • Driven by a 16-bit TERN controller • Support ADC read, ADC-FIFO, FIFO-read modes • Software programmable Power off mode controlled by PD signal. 8 `GR16™ 1.10 GR16 Physical Description The figure below shows the physical layout of the GR16 board. Step 2 Jumper H1 TR, CK, SYNC and Sample Rate Divisor 60 MHz OSC Remove if using external CK H3 FIFO Size 10Ω Resistor A- to INN A+ to INP H2.10 Chip Select /PCS = P16 Analog Inputs A-, A+ (1V-4V) 9 H2.7 Trigger = GND Host I/O GAL GRAB16C0 GRAB1680 GRAB1640 GRAB1600 `GR16™ 1.11 GR16-LM Physical Description The GR16-LM version is the same hardware as the regular GR16, but uses a different GAL set. The jumpers are set differently to accommodate the active high trigger TR. H3 FIFO Size 8MB H2.7 (TR) Trigger is not jumpered to GND 10 GAL GR16-C0 GR16-80 GR16-40 GR16-00 `GR16™ 1.12 GR16 Fifth Board Physical Description When stacking more than four GR16s, a different chip select must be used to operate boards 5 through 8. The image below shows the jumper setting for the 5th GR16. H2.10 Chip Select /PCS = /RTS1 11 U3 SA1 1 SA2 2 SA3 3 SA4 4 SA5 5 /RAM0 6 AD0 7 AD1 8 AD2 9 AD3 10 VCC 11 GND 12 AD4 13 AD5 14 AD6 15 AD7 16 /AD 17 SA6 18 SA7 19 SA8 20 SA9 21 SA17 22 SA1 1 SA2 2 SA3 3 SA4 4 SA5 5 /RAM4 6 AD0 7 AD1 8 AD2 9 AD3 10 VCC 11 GND 12 AD4 13 AD5 14 AD6 15 AD7 16 /AD 17 SA6 18 SA7 19 SA8 20 SA9 21 SA17 22 U13 A0 A1 A2 A3 A4 /CS D0 D1 D2 D3 VCC GND D4 D5 D6 D7 /WR A5 A6 A7 A8 A16 RAM44 U16 A15 A14 A13 /OE /UB /LB D15 D14 D13 D12 GND VCC D11 D10 D9 D8 NC A12 A11 A10 A9 A17 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 SA16 SA1 1 SA15 SA2 2 SA14 SA3 3 /RDF SA4 4 GND SA5 5 GND /RAM1 6 AD15 AD0 7 AD14 AD1 8 AD13 AD2 9 AD12 AD3 10 VCC 11 GND GND 12 VCC AD11 AD4 13 AD10 AD5 14 AD9 AD6 15 AD8 AD7 16 SA22 /AD 17 SA13 SA6 18 SA12 SA7 19 SA11 SA8 20 SA10 SA9 21 SA18 SA17 22 A0 A1 A2 A3 A4 /CS D0 D1 D2 D3 VCC GND D4 D5 D6 D7 /WR A5 A6 A7 A8 A16 RAM44 A15 A14 A13 /OE /UB /LB D15 D14 D13 D12 GND VCC D11 D10 D9 D8 NC A12 A11 A10 A9 A17 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 SA16 SA1 1 SA15 SA2 2 SA14 SA3 3 /RDF SA4 4 GND SA5 5 GND /RAM5 6 AD15 AD0 7 AD14 AD1 8 AD13 AD2 9 AD12 AD3 10 GND VCC 11 VCC GND 12 AD11 AD4 13 AD10 AD5 14 AD9 AD6 15 AD8 AD7 16 SA22 /AD 17 SA13 SA6 18 SA12 SA7 19 SA11 SA8 20 SA9 21 SA10 SA18 SA17 22 VCC R0 5V 10 R8 5V GND 1 2 5V GND 3 AIN 4 AIP 5 GND 6 7 5V RBIAS 8 GND 9 5V 10 GND 11 5V 12 REFEN13 M0 14 M1 15 16 5V C0 A15 A14 A13 /OE /UB /LB D15 D14 D13 D12 GND VCC D11 D10 D9 D8 NC A12 A11 A10 A9 A17 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 SA16 SA1 1 SA15 SA2 2 SA14 SA3 3 /RDF SA4 4 GND SA5 5 GND /RAM2 6 AD15 AD0 7 AD14 AD1 8 AD13 AD2 9 AD12 AD3 10 GND VCC 11 VCC GND 12 AD11 AD4 13 AD10 AD5 14 AD9 AD6 15 AD8 AD7 16 SA22 /AD 17 SA13 SA6 18 SA12 SA7 19 SA11 SA8 20 SA10 SA9 21 SA18 SA17 22 A0 A1 A2 A3 A4 /CS D0 D1 D2 D3 VCC GND D4 D5 D6 D7 /WR A5 A6 A7 A8 A16 RAM44 A15 A14 A13 /OE /UB /LB D15 D14 D13 D12 GND VCC D11 D10 D9 D8 NC A12 A11 A10 A9 A17 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 SA16 SA1 1 SA15 SA2 2 SA14 SA3 3 /RDF SA4 4 GND SA5 5 GND /RAM6 6 AD15 AD0 7 AD14 AD1 8 AD13 AD2 9 AD12 AD3 10 GND VCC 11 VCC GND 12 AD11 AD4 13 AD10 AD5 14 AD9 AD6 15 AD8 AD7 16 SA22 /AD 17 SA13 SA6 18 SA12 SA7 19 SA11 SA8 20 SA10 SA9 21 SA18 SA17 22 H0 1V-4V, ANALOG INPUT1V-4V, ANALOG INPUT+ AV2 RBIAS R9 10 20K VCAP AV2 GND C13 VCAP CK V10 GND V3 V25 GND V40 V3 5V C4 U14 A0 A1 A2 A3 A4 /CS D0 D1 D2 D3 VCC GND D4 D5 D6 D7 /WR A5 A6 A7 A8 A16 RAM44 U17 GND 1 A3 5 A+ 7 9 11 13 GND 15 U4 RRMV VVAAC ADDDD DD PPIR RCVGL GGVVG VV AG D E E A 2 2 K NC F FP AV NC NN AG NC AIN NC AIP D15 AG D14 AV D13 BIAS D12 AG D11 AV D10 AG D9 AV D8 NC D7 M0 D6 S D M1 D5 OR NCP D D Y N C R T D D D N N D D D D D4 DVGC SDRYG VCC01 23 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 A15 A14 A13 /OE /UB /LB D15 D14 D13 D12 GND VCC D11 D10 D9 D8 NC A12 A11 A10 A9 A17 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 SA16 SA1 1 SA15 SA2 2 SA14 SA3 3 /RDF SA4 4 GND SA5 5 GND /RAM3 6 AD15 AD0 7 AD14 AD1 8 AD13 AD2 9 AD12 AD3 10 GND VCC 11 VCC GND 12 AD11 AD4 13 AD10 AD5 14 AD9 AD6 15 AD8 AD7 16 SA22 /AD 17 SA13 SA6 18 SA12 SA7 19 SA11 SA8 20 SA10 SA9 21 SA18 SA17 22 A0 A1 A2 A3 A4 /CS D0 D1 D2 D3 VCC GND D4 D5 D6 D7 /WR A5 A6 A7 A8 A16 RAM44 A15 A14 A13 /OE /UB /LB D15 D14 D13 D12 GND VCC D11 D10 D9 D8 NC A12 A11 A10 A9 A17 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 SA16 SA1 1 SA15 SA2 2 SA14 SA3 3 /RDF SA4 4 GND SA5 5 GND /RAM7 6 AD15 AD0 7 AD14 AD1 8 AD13 AD2 9 AD12 AD3 10 GND VCC 11 VCC GND 12 AD11 AD4 13 AD10 AD5 14 AD9 AD6 15 AD8 AD7 16 SA22 /AD 17 SA13 SA6 18 SA12 SA7 19 SA11 SA8 20 SA10 SA9 21 SA18 SA17 22 H01 2 4 6 8 10 12 14 16 1 3 5 7 9 11 13 15 HDRD16 6666 65555 55555 54 4321 09876 54321 09 U15 A0 A1 A2 A3 A4 /CS D0 D1 D2 D3 VCC GND D4 D5 D6 D7 /WR A5 A6 A7 A8 A16 RAM44 U18 2 4 6 8 10 12 14 16 5V M0 1 3 5 7 9 11 13 15 HDRD16 AD15 AD14 AD13 AD12 AD11 AD10 AD9 AD8 AD7 AD6 AD5 AD4 10UF ADS1610 1112 22222 22223 33 ADS1610 CK4 7890 12345 67890 12 AD3 CK3 PD V3 V3 AD2 CK2 GND GND AD1 R12 SYNC RDY AD0 V3 SYNC /ADL 10K 2 4 6 8 10 12 14 16 C10 U12 A15 A14 A13 /OE /UB /LB D15 D14 D13 D12 GND VCC D11 D10 D9 D8 NC A12 A11 A10 A9 A17 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 LM285 1 +5V 4 V3 2 GND CLK 3 CK AAIN AIP A+ GND REFEN M1 3 4 SA SA12 5 6 SA19 C9 V25 C03 100UF V25 V40 C23 C24 10UF 10UF V40 V10 4 V25A V10A R5 150K 100K SA19 1 SA20 2 SA21 3 C8 5V C7 CAPNP 3 I0R2 160K VCC 6 /RAM 4 AST 5 /AD R10 1K 2K R13 PD R14 V10A 5 PDN 2K 15 14 13 12 11 10 9 7 /RAM0 /RAM1 /RAM2 /RAM3 /RAM4 /RAM5 /RAM6 /RAM7 U10 1A1 1A2 1A3 1A4 2A1 2A2 2A3 2A4 /RDB 1 19 1G 2G 100K SA18 SA17 SA19 SA16 SA15 SA14 1 1 LMC660 U11B 7 V10 LMC660 U11C 8 V25 VCC 1 2 /PCS 3 /RDB 4 /AD 5 /RDF 6 TR 7 AST 8 /RAM AIP R4 AIN R3 AIN C25 A+ 10 A10 AIP C26 10PF 10K 1Y1 1Y2 1Y3 1Y4 2Y1 2Y2 2Y3 2Y4 18 16 14 12 9 7 5 3 D8 D9 D10 D11 D12 D13 D14 D15 AD0 AD1 AD2 AD3 AD4 AD5 AD6 AD7 2 4 6 8 11 13 15 17 /RDB 1 19 74HC244 2 V25 9 1K Y0 Y1 Y2 Y3 Y4 G1 Y5 G2A Y6 G2B Y7 74HC138 2 4 6 8 11 13 15 17 R1 V10 6 V25A10 U8 A B C AD8 AD9 AD10 AD11 AD12 AD13 AD14 AD15 LMC660 U11A 1 V40 RN1 /ADL R11 D0 D1 D2 D3 D4 D5 D6 D7 GND A7 A6 A5 A4 A3 A2 A1 A0 H3.4 = H3.6, 512KB H3.4 = H3.3, 8 MB H3.4 = H3.2, 4 MB C6 5V 2K R6 V25A VCC 16 15 14 13 12 11 GND 10 RDY 9 CK1 SA23 GND CLK HDRD6 VCC VCC R7 V25A BB1117 4040 A0 A1 A2 A3 A4 /CS D0 D1 D2 D3 VCC GND D4 D5 D6 D7 /WR A5 A6 A7 A8 A16 RAM44 J1 U1 VCC 39 VCC 2 SA16 CLK RDY 1 CK 5V 20 GND 40 VCC 1 2 I1 O7 19 /RDB SA15 TR P4 38 37 P14 3 4 3 I2 O6 18 SA 36 35 P6 5 6 SA14 A4 34 33 /INT4 7 8 /RDF A5 4 I3 O5 17 D0 5 I4 O4 16 /AD 32 31 /RTS1 9 10 GND A6 6 15 /RDF 30 29 11 12 GND A7 I5 O3 AD15 /PCS 7 I6 O2 14 PDN 28 27 D15 13 14 AD14 /RD 8 I7 O1 13 AST 26 25 /RST 15 16 AD13 /WR 9 I8 O0 12 /RAM 24 23 RST 17 18 21 20 GND 10 G /OE 11 /CTS1 22 P16 19 AD12 D14 21 GND 20 19 22 D13 23 VCC PAL16V8 18 17 24 AD11 16 15 25 26 D12 27 AD10 AD-FF:/AD=0,/RDF=1,PDN=1,AST=0,/RDB=1,TR=0 14 13 28 12 11 30 /WR 29 AD9 RD_FF:/AD=1,/RDF=0,PDN=0,AST=0,/RDB=0 /RD 31 AD8 RD_AD:/AD=0,/RDF=1,PDN=1,AST=1,/RDB=0 10 9 32 D11 33 SA22 8 7 34 D10 35 SA13 GRAB1600.PDS BASE I/O 0X00 6 5 36 D9 37 SA12 GRAB1640.PDS BASE I/O 0X40 4 3 38 2 1 40 D8 39 SA11 GRAB1680.PDS BASE I/O 0X80 SA10 GRAB16C0.PDS BASE I/O 0XC0 J2 HDRD40 HDRD40 SA18 H1 GND 1 2 TR CK=ADC CLOCK, 60MHZ DEFAULT 3 4 SYNC CK SYNC=MULTIPLE GR16/ADS1610 SYNC SA16 CK4 5 6 CK3 TR=EXTERNAL TRIGGER, ACTIVE LOW SA15 RDY 7 8 RDY DEFAULT TRACE H1.8 = H1.7, 10M SPS 10 CK1 SA14 CK2 9 CUT TRACE, WIRE H1.7 = H1.10, 5M SPS /RDF CUT TRACE, WIRE H1.8 = H1.6, 1.25M SPS HDRD10 GND GND AD15 AD14 H2 AD13 2 /AD AD12 /RDB 1 GND /RDF 3 4 RDY TR=EXTERNAL TRIGGER, ACTIVE LOW VCC AST 5 6 /RAM TR=H2.7 = H2.8=GND, SOFTWARE START SAMPLE AD11 TR 7 8 GND H2.9 = H2.10 = J1.19 HOST SELECT 10 /PCS AD10 P16 9 H2.12 = H2.10 = J2.31 HOST SELECT 11 12 AD9 /CTS1 /RTS1 RDY=0: ADC DATA READY AD8 AST=1: SAxx ADDRESS RESET SA22 HDRD12 P16=J1.19 HOST I/O SELECT SA13 /RTS1=J2.31 HOST I/O SELECT SA12 SA11 SA10 H3 SA18 SA14 1 2 SA22 H3 = FIFO SIZE SELECT HDRD16 C11 V3=3.3V 4 V3 C1 K1 NC OS OS_SMT U2 1 Q12VCC 2 Q11 3 Q6 Q5 Q10 4 Q7 Q8 5 Q4 Q9 6 Q3 RST 7 Q2 CLK 8 GND Q1 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 5V 5V 5V 5V V25 C12 C15 C16 C17 C22 10F V10 U5 GNG VOVO VI A15 A14 A13 /OE /UB /LB D15 D14 D13 D12 GND VCC D11 D10 D9 D8 NC A12 A11 A10 A9 A17 H00 AV2 V40 V25 V10 V3 V3 V3 C14 C18 C19 C20 C21 C3 C5 GND 1 V3 2 VCC 3 C2 A0 A1 A2 A3 A4 /CS D0 D1 D2 D3 VCC GND D4 D5 D6 D7 /WR A5 A6 A7 A8 A16 RAM44 U19 10PF 1 2 3 4 5 6 7 8 U7 Q12VCC Q6 Q11 Q5 Q10 Q7 Q8 Q4 Q9 Q3 RST Q2 CLK GND Q1 4040 U9 1A1 1A2 1A3 1A4 2A1 2A2 2A3 2A4 1Y1 1Y2 1Y3 1Y4 2Y1 2Y2 2Y3 2Y4 18 16 14 12 9 7 5 3 D0 D1 D2 D3 D4 D5 D6 D7 1G 2G 74HC244 VCC 16 15 SA23 14 SA22 13 SA20 12 SA21 11 AST 10 SA12 9 SA13 SA12 SA6 SA5 SA7 SA4 SA3 SA2 1 2 3 4 5 6 7 8 U6 4040 VCC Q12VCC 16 SA11 Q6 Q11 15 SA10 Q5 Q10 14 13 SA8 Q7 Q8 SA9 12 Q4 Q9 11 AST Q3 RST 10 /RAM Q2 CLK 9 SA1 GND Q1 AST=1 SAxx=0 STE/TERN Title HIGH SPEED 16-BIT ADC GRABBER Size Document Number B GRAB16.SCH Date: June 19, 2009 Sheet REV 1 of 1