Quest Self Check 3 Front Panel FET & ZIF Connector Checker

Transcription

1 Quest Self Check 3 Front Panel FET & ZIF Connector Checker for Megatest Q2/62 System Manual P/N: Ver. 3.0 Load Bd P/N: Ver. 1 REFERENCE MANUAL

2 Quest Self Check 3 Front Panel FET & ZIF Connector Checker For System Megatest Q2/62 Manual P/N: Version 3.0 June 28, 2006 Copyright 2006 by Quest Consulting Reproduction of the content in any manner, without express permission of the publisher, is prohibited. No liability is assumed with respect to the use of the information herein. Printed in the United States of America Ver 2.1 Original Self Check 3 Release Ver Skipped, not released to customers Ver 2.5 Added s 40 & 41 Check s for Shorts to each other Ver Added s 42 &43 Check for OPENS on FP Muxes Oct Changed delay to 3ms, SLOP to 15mV to allow for operation on faster PCs Ver 2.7 Fine tuned IPAR: 45.1uA for AGND, 44.8uA for V3, and 45.0uA for positive power supplies, Changed SLOP to 30mV. Ver 3.0 Added leakage tests 39 and 40, more sensitive to leakage between s - s modified to correct for glitch on faster PC host computers Copyright October 2005 by Quest Consulting Page 2

3 Quest Consulting Front Panel FET & Edge Connector Self Check Module (#3) for Megatest Q8000, Megatest Q2/xx, and EPRO 140/142/A/AX Systems Introduction: The Quest Self Check 3 Module is designed to extensively exercise two critical areas of the Systems listed above: - the Front Panel FETs and - the 104-Pin ZIF connection to the Load Board. The standard Self Checks (listed as Self Check 1 and 2, or A and B for EPRO) are not able to run full diagnostics on these two critical areas. Using the processor that original came with the System (running very slow on the standards of today), the number of tests needed and extra test time required made it prohibitive. The high speed processors of today allow these tests to be executed in under a minute. The Self Check 3 Module runs extensive tests that check the operation of the Front Panel FETs and check that there is a good connection between the Front Panel ZIF and the Load Board. The tests are broken into the following Groups: - Continuity on all channels individually to the Load Board - Parallel continuity on channels to the Load Board by Front Panel FET - Parallel continuity with all channels at once to the Load Board - Shorts/Leakage on each FET and channel individually - Verify the +28V, +5V, and 12V raw Power Supplies are making good contact. - Verify the Data Bus (D0 D7) & A0 make good contact - V1, V2, V3 s to the Load Board - Runs all 6 Programmable Power supplies through their limits to verify connections - Checks Sense and all Sense Lines for good connection - Connects AGND through the FETs to verify proper grounding - Each FETs operation between 5Volts to +20Volts in 0.5Volt steps. - Parallel operation of all FETs between full voltage range - Connection of the 6 Special Purpose lines (SP0 SP5). - There are also 3 LEDs of the front of the Load Board that provide a visual check of the +28V, +5V, and 12V supplies. They are designed to go OFF if the supply is missing or below about 1V of its normal level. Copyright October 2005 by Quest Consulting Page 3

4 Operation: The Self Check 3 module consists of the following components: - Quest Self Check 3 Load Board (P/N: ) - Quest Self Check 3 QTL Program o Q8000 SC3Q8K.BIN & SC3.SYM or SC3Q8K.OBJ o Q2/xx SC3.BIN and SC3.SYM o EPRO SC3EPRO.OBJ - Quest Self Check 3 Users Manual Q8000 Operation Requires a Self Check FDM modified to allow for the last set of tests to check the SP lines (contact Quest for modification details). 1. Install the Self Check FDM and the Self Check 3 Load Board. 2. Load the SC3Q8K.OBJ Self Check program (or SC3Q8K.BIN w/escape). 3. Run the program as normal. Q2/52 Operation No additional hardware is required. 1. Install the Self Check 3 Load Board. 2. Load the SC3.OBJ Self Check program or SC3.BIN w/escape. 3. Run the program as normal. Q2/62 Operation Self Check SRC is required. 1. Install the Self Check 3 Load Board. 2. Load the SC3.OBJ Self Check program or SC3.BIN w/escape. 3. Run the program as normal. EPRO 140, 142, 142A, 142AX Operation No additional hardware is required. 1. Install the Self Check 3 Load Board. 2. Load the SC3.OBJ Self Check program. 3. Run the program as normal. Failures for the Self Check 3 program can be checked from the Self Check Listings in this manual. Copyright October 2005 by Quest Consulting Page 4

5 Specifications: Self Check s the Following: Continuity, Leakage, and Functionality of Load Board Connections 1-40 DGND, AGND, Sense (RG/SG) V1 & Sense V1 & PRM1 (V1 to PTU) V2 & Sense V2 & PRM2 (V2 to PTU) V3 & Sense V3 VILC & Sense VILC VBIAS & Sense VBIAS VIHC & Sense VIHC +5 Volts, +28 Volts, - 12 Volts Data Bus - D0 to D7 Address Line - A0 Read ID Control - RID\ Special Purpose Lines (x6) SP0 to SP5 Does not (Not all used in all ers): Write ID Control - WID\ - Pulses LOW on a GETBYTE command - Allows 8-bits of Data to be sent to Load Board - If used, tested with other Self s - Edge Connector Pin 82 Point 1 - TP1 - Only used by Megatest Q2 systems - Timing Generator 0 - Used by Q2 system for timing calibration - Checked with other Self Boards - Edge Connector Pin 22 Spare Pins and Not Used Pins - PRM3, PRM4 - Connector Pins 92, 93, 94,96,97, 98, 99, 100 The Self Check is designed to run on the following test systems: Megatest Q2/62 Other Versions of this Self Check run on: Megatest Q8000 Megatest Q2/52 EPRO 140 EPRO 142 EPRO 142A EPRO 142AX Copyright October 2005 by Quest Consulting Page 5

6 Terminal Commands: After LOAD: When the Self Check 3 Program is loaded or on a B (Begin), the following message will appear: Q2> B Quest Self Check 3 - Q2 Version 3.0 Front Panel FET and ZIF Checker ESCape Only - June 28, 2006 Note: Enter "COMMANDS=1" to see complete Command Summary Chart" This display indicates the Self Check 3 is ready to operate normally and execute Self s. There are also sets of commands that allow the user to control the operation of the program. To see a menu of these commands enter COMMANDS=1 and do a B Begin. Q2> COMMANDS=1 Q2> B The following Parameters can be changed from the Terminal Register SLOP=30mV ; Limits in mvolts PARWAIT=3 ; PARTIME Delay in msec DETAILS=0 ; Produces a 'DETAILED' failure report Note: The following Parameters will change from Manual Listings STEP=#### ; Voltage 'steps' in mvolts XX=## ; Select only one to, ignores others) VLIMIT=### ; Set upper Voltage Limit- Default = 20.0V Present Register Settings: SLOP = 30 mvolts - Default is 30mV PARWAIT = 3 msec - Default is 3mSec DETAILS = 0 - Default is = 0, No Detail Printout STEP = 500 mvolts - Default is 500mv XX = 0 - Default is XX=0, No special selected VLIMIT = mvolts - Default is 20000mV (20.0V) NOTE: All values are reset to defaults on BEGIN unless 'HOLDV=1' is set The BEGIN menu shows the full command set and both the default and present setting of each command. To change a register value, enter the Register name, an = sign, and the new value. Examples: WAITPAR=4 ; Changes the PARTIME command from 3ms (default) to 4ms. STEP=100 ; Changes the Increment to from 500mv (default) to 100mv. ; This will execute 5 times more tests, take 5 times longer to run ; and will no longer follow the correct as in the manual. SLOP=5 ; Changes the test limits from ±30mv (default) to only ±5mv.. Copyright October 2005 by Quest Consulting Page 6

7 These values will continue to be held at the new value until the next B BEGIN is entered which then resets them back to the Default (startup) values. This can be overridden by entering: HOLDV=1 ; Hold s at new settings Now the new values will remain set until HOLDV=0 is entered. Terminal Command Summary Table Command Default Units Comments SLOP=## 30 mv Adjusts the Plus and Minus Resolution STEP=#### 500 mv Adjusts the Step size between Measurements VLIMIT=##### mv Adjusts the Upper Voltage Limit to be tested PARWAIT=## 3 msec Adjusts the PARTIME from I to Measure V XX=## 0 0, 1 40 Selects either ALL s or only 1 to be tested COMMANDS=# 0 0 or 1 0=Do not print menu 1=Print Command Menu HOLDV=# 0 0 or 1 0=Reset s on B 1=Hold s on BEGIN DETAILS=# 0 0 or 1 0=No Detail Printout 1=Detailed Printout on FAIL If the DETAILS Register is set to 1 (DETAILS=1), a failure will create a detailed printout that shows how the test is setup. Example DETAILED Failure Q2> T Failed on Channel 23 Expected Voltage of mvolts With a resolution of 30 mvolts - Plus and Minus With Limits of and mvolts Used PARTIME of 3 mseconds Used STEP resolution of 500 mvolts Other Terminal Self Check Command Examples: VLIMIT=8000 ; Changes the Upper Voltage level from 20V (default) to 8V. ; No tests will go above 8V. XX=14 ; Self will only test 14. XX=0 ; Returns to testing ALL channels. COMMANDS=0 HOLDV=0 ; Returns to not showing the Command Menu Table. ; Returns to having B (Begin) erase any changes to Registers. Copyright October 2005 by Quest Consulting Page 7

8 Self Check Listings s 1 to 99 Dedicated s PS, Data Bus, OPENs, Leakage # Expect for Output between Comment 5 - OPENS All s Purpose: Verify each FET on the Front Panel can individually close and a connection is made to the Self Check 3 Load Board. Action: 0.5ma from the PTU through each FET one at a time, onto the Load Board, through a 22K ohm resistor, and to (thru an 8-to-1 analog 200 ohm mux see Pin 8 of 3E) (also see FET Schematic). Failure: Indicates a bad FET on either the force FETs or possibly on the sense FETs on the Front Panel (see FET Location Table). Could also be the control lines to the FETs not functioning. # Expect for Output between Comment 5 0.5ma 11.15V < 12.0V on each Channel Serial - Each FET closed 1 by 1 s 11 to 21 - OPENS Parallel by IC Q2 / Q8K Purpose: Verify all the FETs used (4 or 2) in each HI-201 on the Front Panel can close at the same time and all connections are made to the Self Check 3 Load Board. Action: 250ua (for each FET - x4 or x2) from the PTU through all the FETs used in the HI- 201, onto the Load Board, through the 22K ohm resistors, and to (thru an 8-to-1 analog 200 ohm mux see Pin 8 of 3E) (also see FET Schematic). Failure: Indicates a bad HI FET (see FET Location Table) # Expect for Output between Comment ma 5.65V < 5.85V on 2, 37 2 s Parallel Chk FET U47 / 12P ma 5.65V < 5.85V on 1, 4, 38, 40 4 s Parallel Chk FET U48 / 13P ma 5.65V < 5.85V on 3, 5, 36, 39 4 s Parallel Chk FET U49 / 14P ma 5.65V < 5.85V on 6, 7, 33, 35 4 s Parallel Chk FET U50 / 15P ma 5.65V < 5.85V on 8, 9, 32, 34 4 s Parallel Chk FET U51 / 16P ma 5.65V < 5.85V on 10, 12, 13, 29 4 s Parallel Chk FET U52 / 17P ma 5.65V < 5.85V on 11, 14, 28, 31 4 s Parallel Chk FET U53 / 18P ma 5.65V < 5.85V on 15, 17, 27, 30 4 s Parallel Chk FET U54 / 19P ma 5.65V < 5.85V on 16, 24, 25, 26 4 s Parallel Chk FET U55 / 20P ma 5.65V < 5.85V on 18, 19, 22, 23 4 s Parallel Chk FET U56 / 21P ma 5.65V < 5.85V on 20, 21 2 s Parallel Chk FET U57 / 22P Copyright October 2005 by Quest Consulting Page 8

9 30 - OPENS Parallel All s Purpose: Verify all FETs on the Front Panel can jointly be closed and all make connection to the Self Check 3 Load Board. Action: 5ma from the PTU to all the FETs at one time, then onto the Load Board, through forty 22K ohm resistors (= 550ohms), and to (thru an 8-to-1 analog 200ohm mux see Pin 8 of 3E) (also see FET Schematic). Should see a 3.25V drop across the 22K resistors (adding in voltage drops across FETs).. Failure: A voltage greater than 4.40V indicates one or more of the forty Front Panel FETs didn t close (see FET Location Table). Note: The voltage is sensed behind the FETs and so the sense FETs are not used on this test. Also the Sense VPAR FET could cause a failure in this test. # Expect for Output between Comment 30 5ma 3.25V < 4.40V Total on All s Parallel - All FETs Closed at once Copyright October 2005 by Quest Consulting Page 9

10 39 to 41 - SHORTs / Leakage All s Purpose: Verify that with the Front Panel FETs closed there are no shorts or leakage of any kind between Channels (tests 39 & 40) and there is little to no leakage out to the Load Board (test 41). Action: Close each Front Panel FET one at a time with Pin Electronics drivers connected (tests 39 & 40), and with Pin Electronics drivers un-connected (test 41). s 39 & 40 Individually connects each to the PTU. The other drivers are connected with 1 to 20 driving a LOW (0V) and with 21 to 40 driving a HIGH (5V) 39 checks the 20 LOW channels while 40 checks the 20 HIGH channels. With VPAR set to 2.5V, there is a 2.5V differential between the channel connected to the PTU and all the other drivers. However, since on the SC3 Load Board, all channels have a 22K ohm resistor in parallel shorted to a common point, all current through the 22K ohm resistor for the being tested must be canceled out to enable an accurate test. To cancel this current, V1 is connected to this common point and is programmed so V x =V1=VPAR=2.5v (see diagram). This forces I x to have 0 current flow. Now, any current that does flow to/from the PTU must be leakage current to/from another channel. This enables the PTU to accurately measure a leakage short of up to 10Meg ohms between any channels. 41 Disconnect PE FETs and V1 VPAR=20V and pass if there is less than 1.0ua of leakage. This will verify that there are no shorts or leakage on each individual channel. Failure: An excess current around 1ua or less indicates the Front Panel should be cleaned. Larger currents indicate probable bad devices or possible shorts on the line. # Expect for Output Comment 39 & V 100na <250na on each Channel Chking Shorts to other Channels Each FET is done individually 41 20V 500na < 1ua on each Channel Leakage Each FET by itself Copyright October 2005 by Quest Consulting Page 10

11 42 & 43 - Open SVPAR MUX Purpose: Verify that there is a connection between Channels and SVPAR through front panel MUX. Action: a current of 41uA from the PTU through a circuit consisting of a front panel FET, a 22K resistor, and a FET to AGND. Check for a voltage drop across this circuit between.875v< x <.925V. Each of the 40 s is tested individually, any failure stops the test. Failure: A votage that is too high or too low indicates a bad front panel SVPAR MUX. # Expect for Output Comment 42 41uA.900V <.925V Check upper voltage limit 43 41uA.900V >.875 Check lower voltage limit 45 to 48 - System s Purpose: Verify the 3 Power Supplies (+28V, +5V, -12V) are all coming out to the Load Board and are relatively accurate. Note: There is a visual check of these supplies using 3 yellow LEDs on the Self Check & 46 Action: [+28V] / [ 12V] - A voltage divider is on the Load Board between +28V and 12V producing a voltage in the middle of +8V. This is checked by forcing IPAR=0na (no current flow) and checking VPAR=+8V (±0.5V). Failure: [+28V] / [ 12V] - A measured voltage much greater than +8V indicates 12V is missing. A measured voltage much lower than +8V indicates the +28V is missing. A failure with a measured voltage too high or too low but closer to +8V indicates a poor connection of one of the supplies or a supply that is out of calibration. 47 & 48 Action: [+5V] Is directly connected through a 10K resistor on the Load Board. The PTU forces IPAR=0na (no current flow) and checks VPAR=+5V(±0.25V). Failure: [+5V] A extremely low reading indicates +5V is missing. Other readings indicated a poor connection. #s Expect for Output between Comment 45 & 46 0na V > 7.50V to < 8.50V +8V - Divide +28V and 12V (= +8) 47 & 48 0na V > 4.75V to < 5.25V +5V - Direct Wire to +5V Copyright October 2005 by Quest Consulting Page 11

12 50 to 87 - Data Bus and A0 s Purpose: Verifies that the 8 Data Bus lines (D0 D7) are all coming onto the Load Board and that A0 (Address Bus) controls them correctly. Action: Four sets of patterns are written to LPORTB all Zeros, all Ones, and alternating bits ( 55 and AA hex). The bits are then individually connected to all channels. The PTU forces 0na (no current flow) and verifies each bit is at the correct VPAR voltage level (less than 1.0V=LOW or greater than 3.0V=HIGH). Failure: Normal failure would indicate a poor connection to the Load Board or shorted to a HIGH or a LOW. s 50 to 57 - Data Bus = 00 hex # Expect for Output between Comment 50 0na 0.00V < 1.0V on ALL Channels Bit 0 = Low (Data Bus = ) 51 0na 0.00V < 1.0V on ALL Channels Bit 1 = Low (Data Bus = ) 52 0na 0.00V < 1.0V on ALL Channels Bit 2 = Low (Data Bus = ) 53 0na 0.00V < 1.0V on ALL Channels Bit 3 = Low (Data Bus = ) 54 0na 0.00V < 1.0V on ALL Channels Bit 4 = Low (Data Bus = ) 55 0na 0.00V < 1.0V on ALL Channels Bit 5 = Low (Data Bus = ) 56 0na 0.00V < 1.0V on ALL Channels Bit 6 = Low (Data Bus = ) 57 0na 0.00V < 1.0V on ALL Channels Bit 7 = Low (Data Bus = ) s 60 to 67 - Data Bus = FF hex # Expect for Output between Comment 60 0na 5.00V > 3.0V on ALL Channels Bit 0 = High (Data Bus = ) 61 0na 5.00V > 3.0V on ALL Channels Bit 1 = High (Data Bus = ) 62 0na 5.00V > 3.0V on ALL Channels Bit 2 = High (Data Bus = ) 63 0na 5.00V > 3.0V on ALL Channels Bit 3 = High (Data Bus = ) 64 0na 5.00V > 3.0V on ALL Channels Bit 4 = High (Data Bus = ) 65 0na 5.00V > 3.0V on ALL Channels Bit 5 = High (Data Bus = ) 66 0na 5.00V > 3.0V on ALL Channels Bit 6 = High (Data Bus = ) 67 0na 5.00V > 3.0V on ALL Channels Bit 7 = High (Data Bus = ) s 70 to 77 - Data Bus = 55 hex # Expect for Output between Comment 70 0na 5.00V for HIGH > 3.0V Bit 0 = Low - (Data Bus = ) 71 0na 0.00V for LOW < 1.0V Bit 1 = High - (Data Bus = ) 72 0na 5.00V for HIGH > 3.0V Bit 2 = Low - (Data Bus = ) 73 0na 0.00V for LOW < 1.0V Bit 3 = High - (Data Bus = ) 74 0na 5.00V for HIGH > 3.0V Bit 4 = Low - (Data Bus = ) 75 0na 0.00V for LOW < 1.0V Bit 5 = High - (Data Bus = ) 76 0na 5.00V for HIGH > 3.0V Bit 6 = Low - (Data Bus = ) 77 0na 0.00V for LOW < 1.0V Bit 7 = Low - (Data Bus = ) s 80 to 87 - Data Bus = AA hex # Expect for Output between Comment 80 0na 0.00V for LOW < 1.0V Bit 0 = Low - (Data Bus = ) 81 0na 5.00V for HIGH > 3.0V Bit 1 = High - (Data Bus = ) 82 0na 0.00V for LOW < 1.0V Bit 2 = Low - (Data Bus = ) 83 0na 5.00V for HIGH > 3.0V Bit 3 = High - (Data Bus = ) 84 0na 0.00V for LOW < 1.0V Bit 4 = Low - (Data Bus = ) 85 0na 5.00V for HIGH > 3.0V Bit 5 = High - (Data Bus = ) 86 0na 0.00V for LOW < 1.0V Bit 6 = Low - (Data Bus = ) 87 0na 5.00V for HIGH > 3.0V Bit 7 = High - (Data Bus = ) Copyright October 2005 by Quest Consulting Page 12

13 91, 92, & 93 - PTU to Power Supplies s Purpose: Verify that the OPEN POWER SUPPLY (OPENPSTEST) for V1, V2, and V3 works correctly. V1 and V2 use the Front Panel FETs; PRM1 and PRM2. V3 uses a special circuit with VOUT/VIL. Action: There are 3 diodes to ground connected to the Power Supplies (simulating input protection diodes). The PTU forces a negative current of IPAR=-300ua through the diode (positive for the negative V3 supply) creating about a 0.7V drop. VPAR tests for less than 1.0V. Failure: An excessive voltage indicates either a poor Load Board connection on V1/V2, SV1/SV2, PRM1/PRM2 or a bad PRM1/PRM2 FET (see FET Table). A V3 failure indicates either a bad Load Board connection on V3 / SV3 or a problem somewhere else in the tester. Note: PRM3 is not used. # Expect for Output between Comment ua -0.7V for > 1.0V OPENs on V1 using PRM1 FET ua - 0.7V for > 1.0V OPENs on V2 using PRM2 FET ua +0.7V for < 1.0V OPENs on V3 using VOUT/VIL Copyright October 2005 by Quest Consulting Page 13

14 Front Panel FET Location Table Q8000/Q2 Front Panels HI FET Switches Q8K 12P 13P 14P 15P 16P 17P 18P 19P 20P 21P 22P Q2 U47 U48 U49 U50 U51 U52 U53 U54 U55 U56 U57 Pin PRM 1 2 Pin 7 Pin 10 Pin PRM Sense VPAR PRM 3 21 Q8000 Front Panel HI1-1818A-5 Mux s Pin 5 Pin 6 Pin 7 Pin 8 Pin 9 Pin 10 Pin 11 Pin 13 14W PRM1 PRM W W W W W PRM Q2 Front Panel - DG-508 Mux s Pin 4 Pin 5 Pin 6 Pin 7 Pin 9 Pin 10 Pin 11 Pin 12 U PRM1 PRM U U U U U RSENSE PRM3 21 Copyright October 2005 by Quest Consulting Page 14

15 s 100 to PTU to Power Supplies s Purpose: The next 4100 tests (100 x 40 channels and 100 of all Channels) verify that the Front Panel FET for each can successfully handle the full voltage range of the PTU. NOTE: s are numbered in order 1 tests are: , 23 tests are , etc. Action: A current (45.1uA for AGND, 44.8uA for V3, and 45.0uA for positive power supplies) is forced through the Front Panel FET, through the ZIF connector onto the Load Board, through a 22K ohm resistor, and finally into a 1-of-8 FET switch (MUX). The MUX is connected to one of 8 possible sources: V1, V2, V3, VILC, VIHC, VBIAS, +5V, or AGND (see FET Schematic). The selected supplies are programmed to provide voltage levels from 4.50V up to V in 500mv steps. The PTU expects to see, across the 22K resistor, a 1.0v (45.0ua x 22Kohm) lower voltage than is being programmed in the MUX power supply selected. VPAR is measured between +/- 30mv from the expected value. Failure: The tests are very tight but should still pass. Intermittent failures on one channel indicate that the FET for that channel may not be operating at full capability and may need to be replaced. Random intermittent failures indicate that the test is too tight for the board. While the Front Panel boards should pass these very tight tests, some boards seem to always fail once in awhile on random tests for reasons unknown. Solid failures indicate either a non-functional FET or a problem in the control circuit for that FET. FET Schematic PTU to to Load Board to 22Kohm to MUX to Selected Copyright October 2005 by Quest Consulting Page 15

16 s 100 to Expect for Output between PTU to 100 & ua 1.0V > 0.970V to < 1.030V AGND (0.0V) 102 & ua -3.5V >-3.530V to <-3.470V V3 = -4.5V 104 & ua -3.0V >-3.030V to <-2.970V V3 = -4.0V 106 & ua -2.5V >-2.530V to <-2.470V V3 = -3.5V 108 & ua -2.0V >-2.030V to <-1.970V V3 = -3.0V 110 & ua -1.5V >-1.530V to <-1.470V V3 = -2.5V 112 & ua -1.0V >-1.030V to <-0.970V V3 = -2.0V 114 & ua -0.5V >-0.530V to <-0.470V V3 = -1.5V 116 & ua 0V >-0.030V to < 0.030V V3 = -1.0V 118 & ua 0.5V > 0.470V to < 0.530V V3 = -0.5V 120 & ua -1.0V >-1.030V to <-0.970V V1 (0.0V) 122 & ua -0.5V >-0.530V to <-0.470V V1 = 0.500V 124 & ua 0.0V > V to < 0.030V V1 = 1.000V 126 & ua 0.5V > 0.470V to < 0.530V V1 = 1.500V 128 & ua 1.0V >0.970V to <1.030V V1 = 2.000V 130 & ua 1.5V >1.470V to <1.530V V1 = 2.500V 132 & ua 2.0V >1.970V to <2.030V V1 = 3.000V 134 & ua 2.5V >2.470V to <2.530V V1 = 3.500V 136 & ua 3.0V >2.970V to <3.030V V1 = 4.000V 138 & ua 3.5V >3.470V to <3.530V V1 = 4.500V 140 & ua 4.0V >3.970V to <4.030V V1 = 5.000V 142 & ua 4.5V >4.470V to <4.530V V1 = 5.500V 144 & ua 5.0V >4.970V to <5.030V V1 = 6.000V 146 & ua 5.5V >5.470V to <5.530V V1 = 6.500V 148 & ua 6.0V >5.970V to <6.030V V1 = 7.000V 150 & ua 6.5V >6.470V to <6.530V V1 = 7.500V 152 & ua 7.0V >6.970V to <7.030V V1 = 8.000V 154 & ua 7.5V >7.470V to <7.530V V1 = 8.500V 156 & ua 8.0V >7.970V to <8.030V V1 = 9.000V 158 & ua 8.5V >8.470V to <8.530V V1 = 9.500V 160 & ua 9.0V >8.970V to <9.030V V1 = V 162 & ua 9.5V >9.470V to <9.530V V1 = V 164 & ua 10.0V >9.970V to <10.030V V1 = V 166 & ua 10.5V >10.470V to <10.530V V1 =11.500V 168 & ua 11.0V >10.970V to <11.030V V1 =12.000V 170 & ua 11.5V >11.970V to <11.530V V1 =12.500V 172 & ua 12.0V >11.470V to <12.030V V1 =13.000V 174 & ua 12.5V >12.470V to <12.530V V1 =13.500V 176 & ua 13.0V >12.970V to <13.030V V1 =14.000V 178 & ua 13.5V >13.470V to <13.530V V1 =14.500V 180 & ua 14.0V >13.970V to <14.030V V1 =15.000V 182 & ua 14.5V >14.470V to <14.530V V1 =15.500V 184 & ua 15.0V >14.970V to <15.030V V1 =16.000V 186 & ua 15.5V >15.470V to <15.530V V1 =16.500V 188 & ua 16.0V >15.970V to <16.030V V1 =17.000V 190 & ua 16.5V >16.470V to <16.530V V1 =17.500V 192 & ua 17.0V >16.970V to <17.030V V1 =18.000V 194 & ua 17.5V >17.470V to <17.530V V1 =18.500V 196 & ua 18.0V >17.970V to <18.030V V1 = V 198 & ua 18.5V >18.470V to <18.530V V1 = V Copyright October 2005 by Quest Consulting Page 16

17 s 200 to Expect for Output between PTU to 200 & ua 1.0V > 0.970V to < 1.030V AGND (0.0V) 202 & ua -3.5V >-3.530V to <-3.470V V3 = -4.5V 204 & ua -3.0V >-3.030V to <-2.970V V3 = -4.0V 206 & ua -2.5V >-2.530V to <-2.470V V3 = -3.5V 208 & ua -2.0V >-2.030V to <-1.970V V3 = -3.0V 210 & ua -1.5V >-1.530V to <-1.470V V3 = -2.5V 212 & ua -1.0V >-1.030V to <-0.970V V3 = -2.0V 214 & ua -0.5V >-0.530V to <-0.470V V3 = -1.5V 216 & ua 0V >-0.030V to < 0.030V V3 = -1.0V 218 & ua 0.5V > 0.470V to < 0.530V V3 = -0.5V 220 & ua -1.0V >-1.030V to <-0.970V V2 (0.0V) 222 & ua -0.5V >-0.530V to <-0.470V V2= 0.500V 224 & ua 0.0V > V to < 0.030V V2 = 1.000V 226 & ua 0.5V > 0.470V to < 0.530V V2 = 1.500V 228 & ua 1.0V >0.970V to <1.030V V2= 2.000V 230 & ua 1.5V >1.470V to <1.530V V2 = 2.500V 232 & ua 2.0V >1.970V to <2.030V V2 = 3.000V 234 & ua 2.5V >2.470V to <2.530V V2 = 3.500V 236 & ua 3.0V >2.970V to <3.030V V2 = 4.000V 238 & ua 3.5V >3.470V to <3.530V V2 = 4.500V 240 & ua 4.0V >3.970V to <4.030V V2 = 5.000V 242 & ua 4.5V >4.470V to <4.530V V2 = 5.500V 244 & ua 5.0V >4.970V to <5.030V V2 = 6.000V 246 & ua 5.5V >5.470V to <5.530V V2 = 6.500V 248 & ua 6.0V >5.970V to <6.030V V2 = 7.000V 250 & ua 6.5V >6.470V to <6.530V V2 = 7.500V 252 & ua 7.0V >6.970V to <7.030V V2 = 8.000V 254 & ua 7.5V >7.470V to <7.530V V2 = 8.500V 256 & ua 8.0V >7.970V to <8.030V V2 = 9.000V 258 & ua 8.5V >8.470V to <8.530V V2 = 9.500V 260 & ua 9.0V >8.970V to <9.030V V2= V 262 & ua 9.5V >9.470V to <9.530V V2= V 264 & ua 10.0V >9.970V to <10.030V V2 = V 266 & ua 10.5V >10.470V to <10.530V V2 =11.500V 268 & ua 11.0V >10.970V to <11.030V V2 =12.000V 270 & ua 11.5V >11.970V to <11.530V V2 =12.500V 272 & ua 12.0V >11.470V to <12.030V V2 =13.000V 274 & ua 12.5V >12.470V to <12.530V V2 =13.500V 276 & ua 13.0V >12.970V to <13.030V V2 =14.000V 278 & ua 13.5V >13.470V to <13.530V V2 =14.500V 280 & ua 14.0V >13.970V to <14.030V V2 =15.000V 282 & ua 14.5V >14.470V to <14.530V V2 =15.500V 284 & ua 15.0V >14.970V to <15.030V V2 =16.000V 286 & ua 15.5V >15.470V to <15.530V V2 =16.500V 288 & ua 16.0V >15.970V to <16.030V V2 =17.000V 290 & ua 16.5V >16.470V to <16.530V V2 =17.500V 292 & ua 17.0V >16.970V to <17.030V V2 =18.000V 294 & ua 17.5V >17.470V to <17.530V V2 =18.500V 296 & ua 18.0V >17.970V to <18.030V V2 = V 298 & ua 18.5V >18.470V to <18.530V V2 = V Copyright October 2005 by Quest Consulting Page 17

18 s 300 to Expect for Output between PTU to 300 & ua 1.0V > 0.970V to < 1.030V AGND (0.0V) 302 & ua -3.5V >-3.530V to <-3.470V V3 = -4.5V 304 & ua -3.0V >-3.030V to <-2.970V V3 = -4.0V 306 & ua -2.5V >-2.530V to <-2.470V V3 = -3.5V 308 & ua -2.0V >-2.030V to <-1.970V V3 = -3.0V 310 & ua -1.5V >-1.530V to <-1.470V V3 = -2.5V 312 & ua -1.0V >-1.030V to <-0.970V V3 = -2.0V 314 & ua -0.5V >-0.530V to <-0.470V V3 = -1.5V 316 & ua 0V >-0.030V to < 0.030V V3 = -1.0V 318 & ua 0.5V > 0.470V to < 0.530V V3 = -0.5V 320 & ua -1.0V >-1.030V to <-0.970V VIHC (0.0V) 322 & ua -0.5V >-0.530V to <-0.470V VIHC = 0.500V 324 & ua 0.0V > V to < 0.030V VIHC = 1.000V 326 & ua 0.5V > 0.470V to < 0.530V VIHC = 1.500V 328 & ua 1.0V >0.970V to <1.030V VIHC = 2.000V 330 & ua 1.5V >1.470V to <1.530V VIHC = 2.500V 332 & ua 2.0V >1.970V to <2.030V VIHC = 3.000V 334 & ua 2.5V >2.470V to <2.530V VIHC = 3.500V 336 & ua 3.0V >2.970V to <3.030V VIHC = 4.000V 338 & ua 3.5V >3.470V to <3.530V VIHC = 4.500V 340 & ua 4.0V >3.970V to <4.030V VIHC = 5.000V 342 & ua 4.5V >4.470V to <4.530V VIHC = 5.500V 344 & ua 5.0V >4.970V to <5.030V VIHC = 6.000V 346 & ua 5.5V >5.470V to <5.530V VIHC = 6.500V 348 & ua 6.0V >5.970V to <6.030V VIHC = 7.000V 350 & ua 6.5V >6.470V to <6.530V VIHC = 7.500V 352 & ua 7.0V >6.970V to <7.030V VIHC = 8.000V 354 & ua 7.5V >7.470V to <7.530V VIHC = 8.500V 356 & ua 8.0V >7.970V to <8.030V VIHC = 9.000V 358 & ua 8.5V >8.470V to <8.530V VIHC = 9.500V 360 & ua 9.0V >8.970V to <9.030V VIHC = V 362 & ua 9.5V >9.470V to <9.530V VIHC = V 364 & ua 10.0V >9.970V to <10.030V VIHC = V 366 & ua 10.5V >10.470V to <10.530V VIHC =11.500V 368 & ua 11.0V >10.970V to <11.030V VIHC =12.000V 370 & ua 11.5V >11.970V to <11.530V VIHC =12.500V 372 & ua 12.0V >11.470V to <12.030V VIHC =13.000V 374 & ua 12.5V >12.470V to <12.530V VIHC =13.500V 376 & ua 13.0V >12.970V to <13.030V VIHC =14.000V 378 & ua 13.5V >13.470V to <13.530V VIHC =14.500V 380 & ua 14.0V >13.970V to <14.030V VIHC =15.000V 382 & ua 14.5V >14.470V to <14.530V VIHC =15.500V 384 & ua 15.0V >14.970V to <15.030V VIHC =16.000V 386 & ua 15.5V >15.470V to <15.530V VIHC =16.500V 388 & ua 16.0V >15.970V to <16.030V VIHC =17.000V 390 & ua 16.5V >16.470V to <16.530V VIHC =17.500V 392 & ua 17.0V >16.970V to <17.030V VIHC =18.000V 394 & ua 17.5V >17.470V to <17.530V VIHC =18.500V 396 & ua 18.0V >17.970V to <18.030V VIHC = V 398 & ua 18.5V >18.470V to <18.530V VIHC = V Copyright October 2005 by Quest Consulting Page 18

19 s 400 to Expect for Output between PTU to 400 & ua 1.0V > 0.970V to < 1.030V AGND (0.0V) 402 & ua -3.5V >-3.530V to <-3.470V V3 = -4.5V 404 & ua -3.0V >-3.030V to <-2.970V V3 = -4.0V 406 & ua -2.5V >-2.530V to <-2.470V V3 = -3.5V 408 & ua -2.0V >-2.030V to <-1.970V V3 = -3.0V 410 & ua -1.5V >-1.530V to <-1.470V V3 = -2.5V 412 & ua -1.0V >-1.030V to <-0.970V V3 = -2.0V 414 & ua -0.5V >-0.530V to <-0.470V V3 = -1.5V 416 & ua 0V >-0.030V to < 0.030V V3 = -1.0V 418 & ua 0.5V > 0.470V to < 0.530V V3 = -0.5V 420 & ua -1.0V >-1.030V to <-0.970V VILC (0.0V) 422 & ua -0.5V >-0.530V to <-0.470V VILC = 0.500V 424 & ua 0.0V > V to < 0.030V VILC = 1.000V 426 & ua 0.5V > 0.470V to < 0.530V VILC = 1.500V 428 & ua 1.0V >0.970V to <1.030V VILC = 2.000V 430 & ua 1.5V >1.470V to <1.530V VILC = 2.500V 432 & ua 2.0V >1.970V to <2.030V VILC = 3.000V 434 & ua 2.5V >2.470V to <2.530V VILC = 3.500V 436 & ua 3.0V >2.970V to <3.030V VILC = 4.000V 438 & ua 3.5V >3.470V to <3.530V VILC = 4.500V 440 & ua 4.0V >3.970V to <4.030V VILC = 5.000V 442 & ua 4.5V >4.470V to <4.530V V1 = 5.500V 444 & ua 5.0V >4.970V to <5.030V V1 = 6.000V 446 & ua 5.5V >5.470V to <5.530V V1 = 6.500V 448 & ua 6.0V >5.970V to <6.030V V1 = 7.000V 450 & ua 6.5V >6.470V to <6.530V V1 = 7.500V 452 & ua 7.0V >6.970V to <7.030V V1 = 8.000V 454 & ua 7.5V >7.470V to <7.530V V1 = 8.500V 456 & ua 8.0V >7.970V to <8.030V V1 = 9.000V 458 & ua 8.5V >8.470V to <8.530V V1 = 9.500V 460 & ua 9.0V >8.970V to <9.030V V1 = V 462 & ua 9.5V >9.470V to <9.530V V1 = V 464 & ua 10.0V >9.970V to <10.030V V1 = V 466 & ua 10.5V >10.470V to <10.530V V1 =11.500V 468 & ua 11.0V >10.970V to <11.030V V1 =12.000V 470 & ua 11.5V >11.970V to <11.530V V1 =12.500V 472 & ua 12.0V >11.470V to <12.030V V1 =13.000V 474 & ua 12.5V >12.470V to <12.530V V1 =13.500V 476 & ua 13.0V >12.970V to <13.030V V1 =14.000V 478 & ua 13.5V >13.470V to <13.530V V1 =14.500V 480 & ua 14.0V >13.970V to <14.030V V1 =15.000V 482 & ua 14.5V >14.470V to <14.530V V1 =15.500V 484 & ua 15.0V >14.970V to <15.030V V1 =16.000V 486 & ua 15.5V >15.470V to <15.530V V1 =16.500V 488 & ua 16.0V >15.970V to <16.030V V1 =17.000V 490 & ua 16.5V >16.470V to <16.530V V1 =17.500V 492 & ua 17.0V >16.970V to <17.030V V1 =18.000V 494 & ua 17.5V >17.470V to <17.530V V1 =18.500V 496 & ua 18.0V >17.970V to <18.030V V1 = V 498 & ua 18.5V >18.470V to <18.530V V1 = V Copyright October 2005 by Quest Consulting Page 19

20 s 500 to Expect for Output between PTU to 500 & ua 1.0V > 0.970V to < 1.030V AGND (0.0V) 502 & ua -3.5V >-3.530V to <-3.470V V3 = -4.5V 504 & ua -3.0V >-3.030V to <-2.970V V3 = -4.0V 506 & ua -2.5V >-2.530V to <-2.470V V3 = -3.5V 508 & ua -2.0V >-2.030V to <-1.970V V3 = -3.0V 510 & ua -1.5V >-1.530V to <-1.470V V3 = -2.5V 512 & ua -1.0V >-1.030V to <-0.970V V3 = -2.0V 514 & ua -0.5V >-0.530V to <-0.470V V3 = -1.5V 516 & ua 0V >-0.030V to < 0.030V V3 = -1.0V 518 & ua 0.5V > 0.470V to < 0.530V V3 = -0.5V 520 & ua -1.0V >-1.030V to <-0.970V VBIAS (0.0V) 522 & ua -0.5V >-0.530V to <-0.470V VBIAS = 0.500V 524 & ua 0.0V > V to < 0.030V VBIAS = 1.000V 526 & ua 0.5V > 0.470V to < 0.530V VBIAS = 1.500V 528 & ua 1.0V >0.970V to <1.030V VBIAS = 2.000V 530 & ua 1.5V >1.470V to <1.530V VBIAS = 2.500V 532 & ua 2.0V >1.970V to <2.030V VBIAS = 3.000V 534 & ua 2.5V >2.470V to <2.530V VBIAS = 3.500V 536 & ua 3.0V >2.970V to <3.030V VBIAS = 4.000V 538 & ua 3.5V >3.470V to <3.530V VBIAS = 4.500V 540 & ua 4.0V >3.970V to <4.030V VBIAS = 5.000V 542 & ua 4.5V >4.470V to <4.530V V2 = 5.500V 544 & ua 5.0V >4.970V to <5.030V V2 = 6.000V 546 & ua 5.5V >5.470V to <5.530V V2 = 6.500V 548 & ua 6.0V >5.970V to <6.030V V2 = 7.000V 550 & ua 6.5V >6.470V to <6.530V V2 = 7.500V 552 & ua 7.0V >6.970V to <7.030V V2 = 8.000V 554 & ua 7.5V >7.470V to <7.530V V2 = 8.500V 556 & ua 8.0V >7.970V to <8.030V V2 = 9.000V 558 & ua 8.5V >8.470V to <8.530V V2 = 9.500V 560 & ua 9.0V >8.970V to <9.030V V2 = V 562 & ua 9.5V >9.470V to <9.530V V2 = V 564 & ua 10.0V >9.970V to <10.030V V2 = V 566 & ua 10.5V >10.470V to <10.530V V2 =11.500V 568 & ua 11.0V >10.970V to <11.030V V2 =12.000V 570 & ua 11.5V >11.970V to <11.530V V2 =12.500V 572 & ua 12.0V >11.470V to <12.030V V2 =13.000V 574 & ua 12.5V >12.470V to <12.530V V2 =13.500V 576 & ua 13.0V >12.970V to <13.030V V2 =14.000V 578 & ua 13.5V >13.470V to <13.530V V2 =14.500V 580 & ua 14.0V >13.970V to <14.030V V2 =15.000V 582 & ua 14.5V >14.470V to <14.530V V2 =15.500V 584 & ua 15.0V >14.970V to <15.030V V2 =16.000V 586 & ua 15.5V >15.470V to <15.530V V2 =16.500V 588 & ua 16.0V >15.970V to <16.030V V2 =17.000V 590 & ua 16.5V >16.470V to <16.530V V2 =17.500V 592 & ua 17.0V >16.970V to <17.030V V2 =18.000V 594 & ua 17.5V >17.470V to <17.530V V2 =18.500V 596 & ua 18.0V >17.970V to <18.030V V2 = V 598 & ua 18.5V >18.470V to <18.530V V2 = V Copyright October 2005 by Quest Consulting Page 20

21 s 600 to Expect for Output between PTU to 600 & ua 1.0V > 0.970V to < 1.030V AGND (0.0V) 602 & ua -3.5V >-3.530V to <-3.470V V3 = -4.5V 604 & ua -3.0V >-3.030V to <-2.970V V3 = -4.0V 606 & ua -2.5V >-2.530V to <-2.470V V3 = -3.5V 608 & ua -2.0V >-2.030V to <-1.970V V3 = -3.0V 610 & ua -1.5V >-1.530V to <-1.470V V3 = -2.5V 612 & ua -1.0V >-1.030V to <-0.970V V3 = -2.0V 614 & ua -0.5V >-0.530V to <-0.470V V3 = -1.5V 616 & ua 0V >-0.030V to < 0.030V V3 = -1.0V 618 & ua 0.5V > 0.470V to < 0.530V V3 = -0.5V 620 & ua -1.0V >-1.030V to <-0.970V V1 (0.0V) 622 & ua -0.5V >-0.530V to <-0.470V V1 = 0.500V 624 & ua 0.0V > V to < 0.030V V1 = 1.000V 626 & ua 0.5V > 0.470V to < 0.530V V1 = 1.500V 628 & ua 1.0V >0.970V to <1.030V V1 = 2.000V 630 & ua 1.5V >1.470V to <1.530V V1 = 2.500V 632 & ua 2.0V >1.970V to <2.030V V1 = 3.000V 634 & ua 2.5V >2.470V to <2.530V V1 = 3.500V 636 & ua 3.0V >2.970V to <3.030V V1 = 4.000V 638 & ua 3.5V >3.470V to <3.530V V1 = 4.500V 640 & ua 4.0V >3.970V to <4.030V V1 = 5.000V 642 & ua 4.5V >4.470V to <4.530V V1 = 5.500V 644 & ua 5.0V >4.970V to <5.030V V1 = 6.000V 646 & ua 5.5V >5.470V to <5.530V V1 = 6.500V 648 & ua 6.0V >5.970V to <6.030V V1 = 7.000V 650 & ua 6.5V >6.470V to <6.530V V1 = 7.500V 652 & ua 7.0V >6.970V to <7.030V V1 = 8.000V 664 & ua 7.5V >7.470V to <7.530V V1 = 8.500V 656 & ua 8.0V >7.970V to <8.030V V1 = 9.000V 668 & ua 8.5V >8.470V to <8.530V V1 = 9.500V 660 & ua 9.0V >8.970V to <9.030V V1 = V 662 & ua 9.5V >9.470V to <9.530V V1 = V 664 & ua 10.0V >9.970V to <10.030V V1 = V 666 & ua 10.5V >10.470V to <10.530V V1 =11.500V 668 & ua 11.0V >10.970V to <11.030V V1 =12.000V 670 & ua 11.5V >11.970V to <11.530V V1 =12.500V 672 & ua 12.0V >11.470V to <12.030V V1 =13.000V 674 & ua 12.5V >12.470V to <12.530V V1 =13.500V 676 & ua 13.0V >12.970V to <13.030V V1 =14.000V 678 & ua 13.5V >13.470V to <13.530V V1 =14.500V 680 & ua 14.0V >13.970V to <14.030V V1 =15.000V 682 & ua 14.5V >14.470V to <14.530V V1 =15.500V 684 & ua 15.0V >14.970V to <15.030V V1 =16.000V 686 & ua 15.5V >15.470V to <15.530V V1 =16.500V 688 & ua 16.0V >15.970V to <16.030V V1 =17.000V 690 & ua 16.5V >16.470V to <16.530V V1 =17.500V 692 & ua 17.0V >16.970V to <17.030V V1 =18.000V 694 & ua 17.5V >17.470V to <17.530V V1 =18.500V 696 & ua 18.0V >17.970V to <18.030V V1 = V 698 & ua 18.5V >18.470V to <18.530V V1 = V Copyright October 2005 by Quest Consulting Page 21

22 s 700 to Expect for Output between PTU to 700 & ua 1.0V > 0.970V to < 1.030V AGND (0.0V) 702 & ua -3.5V >-3.530V to <-3.470V V3 = -4.5V 704 & ua -3.0V >-3.030V to <-2.970V V3 = -4.0V 706 & ua -2.5V >-2.530V to <-2.470V V3 = -3.5V 708 & ua -2.0V >-2.030V to <-1.970V V3 = -3.0V 710 & ua -1.5V >-1.530V to <-1.470V V3 = -2.5V 712 & ua -1.0V >-1.030V to <-0.970V V3 = -2.0V 714 & ua -0.5V >-0.530V to <-0.470V V3 = -1.5V 716 & ua 0V >-0.030V to < 0.030V V3 = -1.0V 718 & ua 0.5V > 0.470V to < 0.530V V3 = -0.5V 770 & ua -1.0V >-1.030V to <-0.970V V2 (0.0V) 722 & ua -0.5V >-0.530V to <-0.470V V2 = 0.500V 724 & ua 0.0V > V to < 0.030V V2 = 1.000V 726 & ua 0.5V > 0.470V to < 0.530V V2 = 1.500V 728 & ua 1.0V >0.970V to <1.030V V2 = 2.000V 730 & ua 1.5V >1.470V to <1.530V V2 = 2.500V 732 & ua 2.0V >1.970V to <2.030V V2 = 3.000V 734 & ua 2.5V >2.470V to <2.530V V2 = 3.500V 736 & ua 3.0V >2.970V to <3.030V V2 = 4.000V 738 & ua 3.5V >3.470V to <3.530V V2 = 4.500V 740 & ua 4.0V >3.970V to <4.030V V2 = 5.000V 742 & ua 4.5V >4.470V to <4.530V V2 = 5.500V 744 & ua 5.0V >4.970V to <5.030V V2 = 6.000V 746 & ua 5.5V >5.470V to <5.530V V2 = 6.500V 748 & ua 6.0V >5.970V to <6.030V V2 = 7.000V 750 & ua 6.5V >6.470V to <6.530V V2 = 7.500V 752 & ua 7.0V >6.970V to <7.030V V2 = 8.000V 754 & ua 7.5V >7.470V to <7.530V V2 = 8.500V 756 & ua 8.0V >7.970V to <8.030V V2 = 9.000V 758 & ua 8.5V >8.470V to <8.530V V2 = 9.500V 760 & ua 9.0V >8.970V to <9.030V V2 = V 762 & ua 9.5V >9.470V to <9.530V V2 = V 764 & ua 10.0V >9.970V to <10.030V V2 = V 766 & ua 10.5V >10.470V to <10.530V V2 =11.500V 768 & ua 11.0V >10.970V to <11.030V V2 =12.000V 770 & ua 11.5V >11.970V to <11.530V V2 =12.500V 772 & ua 12.0V >11.470V to <12.030V V2 =13.000V 774 & ua 12.5V >12.470V to <12.530V V2 =13.500V 776 & ua 13.0V >12.970V to <13.030V V2 =14.000V 778 & ua 13.5V >13.470V to <13.530V V2 =14.500V 780 & ua 14.0V >13.970V to <14.030V V2 =15.000V 782 & ua 14.5V >14.470V to <14.530V V2 =15.500V 784 & ua 15.0V >14.970V to <15.030V V2 =16.000V 786 & ua 15.5V >15.470V to <15.530V V2 =16.500V 788 & ua 16.0V >15.970V to <16.030V V2 =17.000V 790 & ua 16.5V >16.470V to <16.530V V2 =17.500V 792 & ua 17.0V >16.970V to <17.030V V2 =18.000V 794 & ua 17.5V >17.470V to <17.530V V2 =18.500V 796 & ua 18.0V >17.970V to <18.030V V2 = V 798 & ua 18.5V >18.470V to <18.530V V2 = V Copyright October 2005 by Quest Consulting Page 22

23 s 800 to Expect for Output between PTU to 800 & ua 1.0V > 0.970V to < 1.030V AGND (0.0V) 802 & ua -3.5V >-3.530V to <-3.470V V3 = -4.5V 804 & ua -3.0V >-3.030V to <-2.970V V3 = -4.0V 806 & ua -2.5V >-2.530V to <-2.470V V3 = -3.5V 808 & ua -2.0V >-2.030V to <-1.970V V3 = -3.0V 810 & ua -1.5V >-1.530V to <-1.470V V3 = -2.5V 812 & ua -1.0V >-1.030V to <-0.970V V3 = -2.0V 814 & ua -0.5V >-0.530V to <-0.470V V3 = -1.5V 816 & ua 0V >-0.030V to < 0.030V V3 = -1.0V 818 & ua 0.5V > 0.470V to < 0.530V V3 = -0.5V 820 & ua -1.0V >-1.030V to <-0.970V VIHC (0.0V) 822 & ua -0.5V >-0.530V to <-0.470V VIHC = 0.500V 824 & ua 0.0V > V to < 0.030V VIHC = 1.000V 826 & ua 0.5V > 0.470V to < 0.530V VIHC = 1.500V 828 & ua 1.0V >0.970V to <1.030V VIHC = 2.000V 830 & ua 1.5V >1.470V to <1.530V VIHC = 2.500V 832 & ua 2.0V >1.970V to <2.030V VIHC = 3.000V 834 & ua 2.5V >2.470V to <2.530V VIHC = 3.500V 836 & ua 3.0V >2.970V to <3.030V VIHC = 4.000V 838 & ua 3.5V >3.470V to <3.530V VIHC = 4.500V 840 & ua 4.0V >3.970V to <4.030V VIHC = 5.000V 842 & ua 4.5V >4.470V to <4.530V VIHC = 5.500V 844 & ua 5.0V >4.970V to <5.030V VIHC = 6.000V 846 & ua 5.5V >5.470V to <5.530V VIHC = 6.500V 848 & ua 6.0V >5.970V to <6.030V VIHC = 7.000V 850 & ua 6.5V >6.470V to <6.530V VIHC = 7.500V 852 & ua 7.0V >6.970V to <7.030V VIHC = 8.000V 854 & ua 7.5V >7.470V to <7.530V VIHC = 8.500V 856 & ua 8.0V >7.970V to <8.030V VIHC = 9.000V 858 & ua 8.5V >8.470V to <8.530V VIHC = 9.500V 860 & ua 9.0V >8.970V to <9.030V VIHC = V 862 & ua 9.5V >9.470V to <9.530V VIHC = V 864 & ua 10.0V >9.970V to <10.030V VIHC = V 866 & ua 10.5V >10.470V to <10.530V VIHC =11.500V 868 & ua 11.0V >10.970V to <11.030V VIHC =12.000V 870 & ua 11.5V >11.970V to <11.530V VIHC =12.500V 872 & ua 12.0V >11.470V to <12.030V VIHC =13.000V 874 & ua 12.5V >12.470V to <12.530V VIHC =13.500V 876 & ua 13.0V >12.970V to <13.030V VIHC =14.000V 878 & ua 13.5V >13.470V to <13.530V VIHC =14.500V 880 & ua 14.0V >13.970V to <14.030V VIHC =15.000V 882 & ua 14.5V >14.470V to <14.530V VIHC =15.500V 884 & ua 15.0V >14.970V to <15.030V VIHC =16.000V 886 & ua 15.5V >15.470V to <15.530V VIHC =16.500V 888 & ua 16.0V >15.970V to <16.030V VIHC =17.000V 890 & ua 16.5V >16.470V to <16.530V VIHC =17.500V 892 & ua 17.0V >16.970V to <17.030V VIHC =18.000V 894 & ua 17.5V >17.470V to <17.530V VIHC =18.500V 896 & ua 18.0V >17.970V to <18.030V VIHC = V 898 & ua 18.5V >18.470V to <18.530V VIHC = V Copyright October 2005 by Quest Consulting Page 23

24 s 900 to Expect for Output between PTU to 900 & ua 1.0V > 0.970V to < 1.030V AGND (0.0V) 902 & ua -3.5V >-3.530V to <-3.470V V3 = -4.5V 904 & ua -3.0V >-3.030V to <-2.970V V3 = -4.0V 906 & ua -2.5V >-2.530V to <-2.470V V3 = -3.5V 908 & ua -2.0V >-2.030V to <-1.970V V3 = -3.0V 910 & ua -1.5V >-1.530V to <-1.470V V3 = -2.5V 912 & ua -1.0V >-1.030V to <-0.970V V3 = -2.0V 914 & ua -0.5V >-0.530V to <-0.470V V3 = -1.5V 916 & ua 0V >-0.030V to < 0.030V V3 = -1.0V 918 & ua 0.5V > 0.470V to < 0.530V V3 = -0.5V 920 & ua -1.0V >-1.030V to <-0.970V VILC (0.0V) 922 & ua -0.5V >-0.530V to <-0.470V VILC = 0.500V 924 & ua 0.0V > V to < 0.030V VILC = 1.000V 926 & ua 0.5V > 0.470V to < 0.530V VILC = 1.500V 928 & ua 1.0V >0.970V to <1.030V VILC = 2.000V 930 & ua 1.5V >1.470V to <1.530V VILC = 2.500V 932 & ua 2.0V >1.970V to <2.030V VILC = 3.000V 934 & ua 2.5V >2.470V to <2.530V VILC = 3.500V 936 & ua 3.0V >2.970V to <3.030V VILC = 4.000V 938 & ua 3.5V >3.470V to <3.530V VILC = 4.500V 940 & ua 4.0V >3.970V to <4.030V VILC = 5.000V 942 & ua 4.5V >4.470V to <4.530V V1 = 5.500V 944 & ua 5.0V >4.970V to <5.030V V1 = 6.000V 946 & ua 5.5V >5.470V to <5.530V V1 = 6.500V 948 & ua 6.0V >5.970V to <6.030V V1 = 7.000V 950 & ua 6.5V >6.470V to <6.530V V1 = 7.500V 952 & ua 7.0V >6.970V to <7.030V V1 = 8.000V 954 & ua 7.5V >7.470V to <7.530V V1 = 8.500V 956 & ua 8.0V >7.970V to <8.030V V1 = 9.000V 958 & ua 8.5V >8.470V to <8.530V V1 = 9.500V 960 & ua 9.0V >8.970V to <9.030V V1 = V 962 & ua 9.5V >9.470V to <9.530V V1 = V 964 & ua 10.0V >9.970V to <10.030V V1 = V 966 & ua 10.5V >10.470V to <10.530V V1 =11.500V 968 & ua 11.0V >10.970V to <11.030V V1 =12.000V 970 & ua 11.5V >11.970V to <11.530V V1 =12.500V 972 & ua 12.0V >11.470V to <12.030V V1 =13.000V 974 & ua 12.5V >12.470V to <12.530V V1 =13.500V 976 & ua 13.0V >12.970V to <13.030V V1 =14.000V 978 & ua 13.5V >13.470V to <13.530V V1 =14.500V 980 & ua 14.0V >13.970V to <14.030V V1 =15.000V 982 & ua 14.5V >14.470V to <14.530V V1 =15.500V 984 & ua 15.0V >14.970V to <15.030V V1 =16.000V 986 & ua 15.5V >15.470V to <15.530V V1 =16.500V 988 & ua 16.0V >15.970V to <16.030V V1 =17.000V 990 & ua 16.5V >16.470V to <16.530V V1 =17.500V 992 & ua 17.0V >16.970V to <17.030V V1 =18.000V 994 & ua 17.5V >17.470V to <17.530V V1 =18.500V 996 & ua 18.0V >17.970V to <18.030V V1 = V 998 & ua 18.5V >18.470V to <18.530V V1 = V Copyright October 2005 by Quest Consulting Page 24

25 s 1000 to Expect for Output between PTU to 1000 & ua 1.0V > 0.970V to < 1.030V AGND (0.0V) 1002 & ua -3.5V >-3.530V to <-3.470V V3 = -4.5V 1004 & ua -3.0V >-3.030V to <-2.970V V3 = -4.0V 1006 & ua -2.5V >-2.530V to <-2.470V V3 = -3.5V 1008 & ua -2.0V >-2.030V to <-1.970V V3 = -3.0V 1010 & ua -1.5V >-1.530V to <-1.470V V3 = -2.5V 1012 & ua -1.0V >-1.030V to <-0.970V V3 = -2.0V 1014 & ua -0.5V >-0.530V to <-0.470V V3 = -1.5V 1016 & ua 0V >-0.030V to < 0.030V V3 = -1.0V 1018 & ua 0.5V > 0.470V to < 0.530V V3 = -0.5V 1020 & ua -1.0V >-1.030V to <-0.970V VBIAS (0.0V) 1022 & ua -0.5V >-0.530V to <-0.470V VBIAS = 0.500V 1024 & ua 0.0V > V to < 0.030V VBIAS = 1.000V 1026 & ua 0.5V > 0.470V to < 0.530V VBIAS = 1.500V 1028 & ua 1.0V >0.970V to <1.030V VBIAS = 2.000V 1030 & ua 1.5V >1.470V to <1.530V VBIAS = 2.500V 1032 & ua 2.0V >1.970V to <2.030V VBIAS = 3.000V 1034 & ua 2.5V >2.470V to <2.530V VBIAS = 3.500V 1036 & ua 3.0V >2.970V to <3.030V VBIAS = 4.000V 1038 & ua 3.5V >3.470V to <3.530V VBIAS = 4.500V 1040 & ua 4.0V >3.970V to <4.030V VBIAS = 5.000V 1042 & ua 4.5V >4.470V to <4.530V V2 = 5.500V 1044 & ua 5.0V >4.970V to <5.030V V2 = 6.000V 1046 & ua 5.5V >5.470V to <5.530V V2 = 6.500V 1048 & ua 6.0V >5.970V to <6.030V V2 = 7.000V 1050 & ua 6.5V >6.470V to <6.530V V2 = 7.500V 1052 & ua 7.0V >6.970V to <7.030V V2 = 8.000V 1054 & ua 7.5V >7.470V to <7.530V V2 = 8.500V 1056 & ua 8.0V >7.970V to <8.030V V2 = 9.000V 1058 & ua 8.5V >8.470V to <8.530V V2 = 9.500V 1060 & ua 9.0V >8.970V to <9.030V V2 = V 1062 & ua 9.5V >9.470V to <9.530V V2 = V 1064 & ua 10.0V >9.970V to <10.030V V2 = V 1066 & ua 10.5V >10.470V to <10.530V V2 =11.500V 1068 & ua 11.0V >10.970V to <11.030V V2 =12.000V 1070 & ua 11.5V >11.970V to <11.530V V2 =12.500V 1072 & ua 12.0V >11.470V to <12.030V V2 =13.000V 1074 & ua 12.5V >12.470V to <12.530V V2 =13.500V 1076 & ua 13.0V >12.970V to <13.030V V2 =14.000V 1078 & ua 13.5V >13.470V to <13.530V V2 =14.500V 1080 & ua 14.0V >13.970V to <14.030V V2 =15.000V 1082 & ua 14.5V >14.470V to <14.530V V2 =15.500V 1084 & ua 15.0V >14.970V to <15.030V V2 =16.000V 1086 & ua 15.5V >15.470V to <15.530V V2 =16.500V 1088 & ua 16.0V >15.970V to <16.030V V2 =17.000V 1090 & ua 16.5V >16.470V to <16.530V V2 =17.500V 1092 & ua 17.0V >16.970V to <17.030V V2 =18.000V 1094 & ua 17.5V >17.470V to <17.530V V2 =18.500V 1096 & ua 18.0V >17.970V to <18.030V V2 = V 1098 & ua 18.5V >18.470V to <18.530V V2 = V Copyright October 2005 by Quest Consulting Page 25