Service Manuals, User Guides, Schematic Diagrams or docs for : Keithley 485 485_903_01A

<< Back | Home

Most service manuals and schematics are PDF files, so You will need Adobre Acrobat Reader to view : Acrobat Download Some of the files are DjVu format. Readers and resources available here : DjVu Resources
For the compressed files, most common are zip and rar. Please, extract files with Your favorite compression software ( WinZip, WinRAR ... ) before viewing. If a document has multiple parts, You should download all, before extracting.
Good luck. Repair on Your own risk. Make sure You know what You are doing.

Image preview - the first page of the document

>> Download 485_903_01A documenatation <<

Text preview - extract from the document

MODEL 485
AUTORANGING PICOAMMETER

QUICK REFERENCE GUIDE
INTRODUCTION

This reference and programming guide contains condensed specifica-
tions and information which describes the various features of the
Model 485. Each feature is described in three segments of informa-
tion. The first segment describes the features. The second segment
gives an exact procedure on how to use the feature. The third seg-
ment gives application examples. These segments are brief, but the
information presented in this format is designed for a quick reference
of the Model 485 features and functions. Refer to the Model 485 In-
struction Manual for complete information and essential safety infor-
mation.

With the Model 4853 IEEE-488 interface installed, the Model 485 can
be controlled over the IEEE-488 bus. This booklet also contains infor-
mation concerning Model 485 bus operation. Several example pro-
grams using some commonly used controllers are outlined to get the
Model 485/4853 "up and running".

CONTENTS

CONDENSED SPECIFICATIONS .......................... 2
MODEL485 FEATURES ................................... 5
IEEE-488 PROGRAMMING.. ............................. 13
PROGRAMS ............................................ 18
IBM-PCorXTPersonalComputer.. ....................... 19
(Keithley Model 8573 Interface)
APPLE II (Apple Interface) ............................... 21
HP-85 ................................................. 22
HP-9825A.. ........................................... 23
HP-9816 ............................................... 24
HP-9845B.. ........................................... 25
TEK4052 .............................................. 26
DECLSIll.. ......................... ___. .......... _.- 27
PETlCBM2001 ........................................ 29
EH 7000 Computer ..................................... 30

01984. Keithley Instruments, Inc.
Cleveland, Ohio, U.S.A.
Document Number: 485903-OlA

1
CONDENSED SPECIFICATIONS

Accuracy (1 year) Maximum
18O -2WC Continuous
Range Resolution *(%rdg + countsIt InputS
J
2nA O.lpA 0.4 + 4 35OVdc
20 nA 1 PA 0.4 -t 1 35OVdc
2OilnA 10 pA 0.2 + 1 35OVdc

100 nA 0.15 + 1 35OVdc
1llA 0.1 +1 5OVdc
10 nA
100 nA
0.1
0.1
+1
+1
5OVdc
5OVdc
1
W&h no limitiw resistance: 1OOOVdc with external lOOk series resistance.

INPUT VOLTAGE BURDEN: Less than 2OOhV.
RANGING: Manual or autoranging.
AUTORANGING TIME: 2COms per range.
SElTLING TIME AT DISPLAY: Less than lsec to within 1 cuunt after
ranging.
CONVERSION PERIOD: 300ms.
TEMPERATURE COEFFICIENT: -z f0.1 x applicable accuracy
specification per T.
MAXIMUM COMMON MODE VOLTAGE: BOVrms, DC to 60Hz
sine wave.
ANALOG OUTPUT:
Output Voltage: +lV, = -10000 counts. (Except +lOOmV =
-1OoM) wunts on 2nA range.)
Output Resistance: 1OOOQ.
RELATIVE: Pushbutton allows zeroing of on range readings. Allows
readings to be made with respect to baseline value. Front panel
annunciator indicates REL mode.
DATA STORE and MINIMAX: 100 reading storage capacity. Records
date at one of seven selectable rates from Brdgs/s to lrdg/hr and
manual triggering. Also detects and stores maximum and minimum
readings continuouslywhile in the data store mode.
LOG: Displaysthe logarithm (base 10) of the input current referenced to
1A.

2
SAFETY SYMBOLS AND TERMS

I
The ayrnbojQ on the instrument denotes that user should refer to
the operating section in the Model 455 Instruction Manual.

The WARNING used in this guide explains dangers that could result in
personal injury or death.

SAFETY PRECAUTIONS

1. Before operation, ground the instrument through a properly earth
grounded power receptacle.
2. Before servicing, disconnect the instrument from the power line, all
other equipment and consult the Model 455 Instruction Manual.
3. Do not touch the input terminal while the instrument is turned on or
connacted to any other tast equipment. Common mode voltage may
be prasent.

3
DISPLAY ANNUNCIATORS

the fol\owing annunciators are displayA on the LCD Kiquid Crystal
Display1

AUTO-Indicates that the h+nfel485 is in the autorange mode.
REL--lnticates that the relative mode isselecttxl. The reading is r&t&
to some previous reading.
LOG-Log mode reading is directly in log (base 101.
SO-Indicates that the data store and minimax hold function is run-
ning. Displayed raadjng is present input.
RCL-Indicates that the displayed reading is recalled data.
BAT-Indicates that the battery requires recharghg (operates only if
the battery pack option Model 1758, is instaliedl.
ZERO CHECK-Indicates that the Model 485 is in the zero check
mode. Input impedance changes when in the zero check mode.
nA, & or mA-Nanoamps, microamps or milliamps selected. Read
measurement directly from the display. (e.g. 1.2345fll
RMT--(Remote) Model 485 is being controlled over the IEEE-488 bus
(Model 4853 installed).
CAL-Indicates that the Model 435 is in the calibration mode.

4
MODEL 485 FEATURES

RANGE t2nA to 2mAl

I z&v I 35ov 5ov 5ov 5ov
MAX MAX MAX MAX

Description
The range buttons se&t the desired range of current measurement for
the Model 485. The range may' be selected manually or automatically.
With manual range selection always use the range that allows the
greatest amount of resolution.
Operation
Manual
1. Determine signal to be measured.
2. Press appmpriate range button.
3. Apply signal.
Auto
1. Press the AUTO button.
2. Apply signal.

5
ZERO CHECK

DesctiptIon
The ZERO CHECK button is used to correct interna ofFsets and also
protects the sensitiveinput circuitry from build up during overloads. In
the zero check mode or input overload, the input impedance of the
Modal 495 is changed as outlined in the following table.

INPUT RESISTANCE WITH ZERO CHECK ENABLED

Current Maximum Effective Impedance In
Ranae lmut Resistance Zero Check/Overload
2nA 1 1GMl 9MWX3IpF

1. Select range.
2. Depress ZEFtO CHECK. The ZERO CHECK button operatas on the
push-push principle. That is, pressing in the button locks the instru-
ment in zero check, pressingthe button again releasesthe zero check
mode.
Typical Use
Used in zeroing the 2nA range for precise measurements. Refer to
paragraph 2.72 in the Model 495 Instruction Manual.

6
REL (Relative Function)

REL

Description
The relativefunction serves as a means of baselinesuppressionallowing
a stored offset value to be subtracted from subsequent readings. When
the REL button is pressed, the instrument stores the baseline reading
with the next conversion. All subsequent readings represent the di-
ferences between the applied signal level and the stored baseline. The
stored baseline can be as small as the resolution of the instrument will
allow or as large as full range.

It is important to note that the REL function reduces the dynamic range
of measurements by that level (stored baseline). For example: assume
that the REL level is + Id and the Model 495 is manuallyset to the w
range. The maximum positive displayed reading, before overranging,
would be + 0.9999& This is because the A/D converter would be see-
ing + 1.9999fi to + 0.9999fi (2.999&A) as compared to the normal
-1.9999fi to + 1.9999d (3.9998fi). Actually, the dynamic range is
reduced by lfi or 10,000 counts. The effects on dynamic range can be
reduced by selecting e higher range or using autorange.

Operation
1. Select measurement mode and range. For example: normal measure-
ment mode and the w range.
2. Press REL. The display reads zero.
3. The value that appeared on the display is now the stored offset.

Typical Use
1. Nulling out external source offset (e.g. calibrator offset).
2. Nulling out desired levels of offset (e.g. electrode dark current of
phototube).

7
LOG (Log Function)

Description
The log function gives the log (base 101 of the measured input current
referenced to 1A. Log can be used to make any current level the 0.0
(zero) point for log measurements. This can be done by selecting
autorange and log. Then measuring the desired current that is to be the
0.0 [zero) point. The logarithm is taken on the absolute value of the
measurement so that both positive and negative currents can be
displayed as e log. Press the REL button and the display wiil read 0.0
(zero). The measured current is now the 0.0 (zero) point for the log
function. The mathematical equation for the log function is shown as
follows:

Input
Display = Log -
I 1 Amp I

Operation (referenced to IA)
1. Select the auto range mode.
2 Apply the source.
3. Press the LOG button. The LOG annunciator on the displayturns on.
4. Take the log reading from the display.

Typical Use
1. For use in measuring e wide range of current. Nuclear reactors have
various outputs of current that could be compressed (in readings on-
ly) by using the log function.
2 Measuring the current output of a phototube. REL can be used to
nu[l the dark current of the phototube.
DATA STORE (100 Point Data Store1

Description
The 100 point data store function servesto save up to 100 points of data
at the rate of one of six selectable rates from every reading (3 per
second) to one reading per hour. Also, manual data entry is available
(RN. This feature is useful in applications where data is required to be
logged over a period of time.

Operation
1. Connect desired measurement configuration to the Model 485.
2. Select rate of storage and begin data store:
A. Press and hold in the STO/CLR button.
6. The rates are scrolled on the display. Tithe rates are described
below).
C. Release the STWCLR button when the desired rate is displayed.
D. The ST0 annunciator turns on indicating that the data is being
stored at the selected rate.

Typical Use
1. Saving data points of current drift of a low leakage device such as e
FEr.
2. Monitoring and saving current levels that fluctuate over a period of
time.
r = 0 (every reading)
r = 1 (1 reading per second)
r = 2 (1 reading per 10 seconds)
r = 3 I1 reading per minute)
r = 4 I1 reading per 10 minutes)
r = 5 (1 reading per hour)
T = S (every time STOKLR is pressed)
STO/CLR (Store end Clear Function)
Description
The STOKLR button is an internal part of the data store function. The
button has several functions that are listad as follows:
1. Starts the data store operation.
2. Turns off the data store operation.
3. Selects the storage rate.
4. In the R6 data rate mode the STOKLR button (when pressed) trlg-
gers the Model 485 to store a reading.
5. In the talk only mode, the STOKLR button selects the talk rate. The
store mode must be disabled for this function.

Operation
1. Pressthe STOKLR button to start the data store operation ISTO an-
nunciator on the displayis turn on). At this point the Model 465 starts
storing readings.
2. Hold in the STOKLR button to select the storage rate. The rates are
scmlled on the display. Release the STOlCLR button when the
desired rate is displayed.
3. Press the STOKLR button to stop the data store operation. All data
is retained until e new store cycle has commenced.
4. When in the R6 data rate mode, prass the STOKLR button each
time a reading is to be stored. This data rate mode is used for custom
rate data storage.
5. Using the IEEE interface the STOKLR button can be used to select
the talk rate. Refer to page 17.

10
RCL (Recall Function of DATA STORE)
Description
The RCL button is used to retrieve data that has bean stored using the
store/clear function.

Operation
1. Press and hold in the RCL button. The display scrolls through the
data points and minimum/maximum readings. The first data point
displayed is the last stored reading. The next two data points are the
HI and LO readings made during that store cycle. Notice that the
longer the RCL button is held in the faster the data points scroll on
the display.
2. Release the RCL button at the desired data point and note the
reading on the display. The data pointer can be incremented by steps
of one by momentarily holding in the RCL button.
3. Turn off the data store by pressing the STO/CLR button. All stored
data is retained until a new store cycle has commenced.

MidMax HOLD
Description
The minimum/maximum hold feature detects and holds the highest and
lowest readingswhile in the data store mode. This action is independent
of the storage rate and runs at a rate of three readings per second. This
function works in conjunction with the data store mode. The minimum
and maximum readings are continuouslyupdated while in the data store
mode.

Operation
1. Use the data store mode to save a number of readings.
2 Press and hold in the RCL button. The display scrolls through the
data points and the minimumlmaxlmum points. The first data point
displayed is the last data point that was stored. The next two data
points are the maximum and minimum readings made during that
store cycle.
3. Release the RCL button at the desired data point (min, max or nomral
data point) and note the reading on the display. The data pointer can
be incremented by steps of one by momentarily holding in the RCL
button.

Typical Use
Save up to 100 points of output current data along with the minimum
and maximum readings of 1pA source that needs to be verified for
calibration.

11
DIGITAL CALIBRATION

~ha diiitat calibration feature eliminates calibration potentiometers. All
calibrationfactors for each range are stored in non-volatileRAM;The rn-
strument can be calibrated from the front panel or with the optional
4353 IEEE interface. With the Model 4653 IEEE-488 interface installed,
the Model 465 can be calibrated much faster using an automated
system. Front panel digital calibration is outlined as follows:
NOTE
The following is an actual calibration procedure for
the 2Ofi range. If recalibrationis not necessary, then
do not move the calibrationjumper. Leave the jumper
in the disable position. Refer to the Maintenance Sec-
tion of the 465 Instruction Manual for jumper place-
ment.
1. Move the calibrationjumper to the enable position.
2. Turn on the Model 465.
3. Press the REL and LOG buttons simultaneously until the message
"CAL" is displayed. Release the buttons. The Model 465 is now in
the calibration mode as indicated by the "CAL" annunciator.
4. Apply the proper signal or level to the Model 465 input. Example:
place the Model 465 to the 2Ofi range and apply 19.066~.
NOTE
Consult the Model 465 Instruction Manual for detailed
methods of creating the proper calibration levels.
5. Adjust the display accordinglywith the usa of the STOKLR and RCL
buttons. The STOKLR button increments the displayed reading.
The RCL button decrements the displayed reading.
6. Press the LOG and REL button simultaneously until the massage
"STOR" is displayed. The "new" calibrationpoint for the 2&A range
is now permanently stored. This new constant remains as is until
changad.
7. To return to normal operation, turn off the instrument momentarily,
then back on.
8. Turn the instrument off and place the calibrationjumper in the disable
position to prevent inadvertent calibration of the instrument.

Consult the Model 465 Instruction Manual for complete details concern-
ing Model 465 calibration.The preceding procedure is presented here to
remind the user that front panel digital calibration is available on the
Model 465.

IEEE-468 option: Allows the user to calibrate the instrument over the
IEEE-468 bus. With the IEEE48 interface installed (option 4653). the
Model 465 can be calibrated on most automated calibration systems.

12
IEEE-488 PROGRAMMING

Tha K&hlay Model 485 has an optional IEEE-488 interfaca (Model
4853) which can be included with the instrument or added later.
Inclusionof the interface option is apparent by the connector and
address switch at the rear panel. The field installableoption kit in-
cludes a replacement top cover with appropriate access openings
on the rear panel. The following listsall the commands availableto
the Model 485.

RANGE: RO = Auto Range
(RO ignored in calibration mode)
Rl = 2nA
R2 = 20 nA
R3 = 200 nA
R4= Z/UI
R5 = 20/A
R6=266d
R7= 2mA
LOG: W=Off
Dl = On
RELATIVE: M=Off
21 = On
ZERO CHECK: CO=Off
Cl = On
TRIGGER: To = Continuous on Talk
Tl = One-shot on Talk
T2 = Continuous on GET
T3 = Oneshot on GET
T4 = Continuous on "X"
T6 = One-shot on "X"
EOI: KO = EOI is transmitted on the last byte
out.
Kl = EOI is not transmitted.
STORE: L6 = Store Calibration Constants
DIGITAL
CALIBRATION: V+n.nnnnE+nn
n = CalibrationValue
SRQ: Mnnn
nnn = 0 to 255(base 10)
MO = Clear SRQ data mask
Ml = Reading Overflow
ME = Reading Done
M9 = Reading Done or Reading Overflow

13
Ml6 = Busy
Ml7 = Busy or Reading Overflow
M24 = Busy or Reading Done
M25 = Busy, Reading Done or Reading
ovemow
P.432 = Clear SRQ Errol mask
M33 = IDDCQ
M34 = IDDC
M35 = IDDC or IDDCO
M36 = Not in Remote
M37 = Not in Remote or IDDCO
M33 = Not in Remota or IDDC
M39 = Not in Remote, IDDC or IDDCO
STATUS WORD: UO = Output Status Word on next read.
DATA FORMAT: GO = Send Prefuc
Gl = Do Not Send Prefix
TERMINATOR: Y(ASCII) = ASCII character
Y(CR LF) = CR LF
YiLF CR) = LF CR
Y(X) = None
EXECUTE: X = Execute other device-dependent
commands.

POWER UP DEFAULT CONDITIONS

VALUE/STATUS
Turned Qff
Reflects Front Panel Buttons
Reflects Front Panel Button
LOG Do) off
REIATNE m off
CALIBRATION MOM w
TRIGGEFI (TO) Continuous on Talk
EQI (KC0EOI is tranm-iti cm last byte
out.
(MOOO) No SRQ
Standard Output

DATA FORMAT (GO1Prefix Enabled
(CR) ILFI

14
MODEL 4953 PRIMARY ADDRESS SWITCH SET AT 22 (10110)

TALKER ONLY
(TO) MODE

:1pljijJpg
1 ADDRESSABLE
MODE

DATA FORMAT:
(Reading)

NDCA * 1 .2345 E-9 CR LF

1 ~iiiti&.%@

N = Normal
0 = Overflow
C = Zero Check
Z = Relative

15
STATUS:

485 CDRZKT MdMeY CR LF

r 7YzJLsIgdl,D.

DEFAULT:

4 8 5 C x D 0 R x Z 0 K 0 T 0 M 0 0 0 (CR) ILFI

R.sfk?cts
Front Panel

Reflects . 1
Front Panel

16
Talk Only Operation
Description
The talk oniy mode may be used to send data to a listenonly device such
as a printer. When the Model 465 is in the talk only mode, it ignores
commands given over the bus. The talk only mode is enabled by placing
the TOlADDRSSABLE switch in the TO position and then cycling
power to the instrument. The default talk rate is three readings per se-
cond (every reading). However, a different talk rate can be selected by
performing the following procedure.

Operation
1. Enable the talk only mode. Cycle power to the instrument.
2. Press and hold in the STOKLR button. The following talk rates scroll
on the display:
r = 0 (every reading)
r = 1 (1 reading per second)
r = 2 (1 reading per 10 seconds)
r = 3 (1 reading per minute)
r = 4 (1 reading per 10 minutes)
r = 5 (1 reading per hour)
r = 6 (1 reading per every time STOKLR is pressed)
3. Release the STOlCLR button when the desired talk rate is displayed.
At this point the ST0 annunciator appears on the display indicating
that the instrument is talking at the selected rate.
4. Turn off the data store operation by pressing the STOKLR button. ,
Notice that the ST0 annunciator turns off.

NOTE
The instrument remains in the selected talk rate until a
new rate is selected or power is cycled.

17
PROGRAMS

The fallowing programs are designed to be a simple aid to the war.
They are not intended to suit specific needs. Detailed programming in-
formation can be found in the manual.

These programs display one readhg at the output of the controller. The
program provides an ASCII string variable output of the form:
NDCA + O.DoOO+OCR LF
The note at the end of each program indicates modificationsto provide
a numeric variable (A) in exponential form:
+o.ooao+o

18
IBM PERSONAL COMPUTER XT or PC
(Keithley Instruments Model 8573 GPIB Interface)
The following program sends a command string to the Model 485 from
an \BM PC or XT computer and displaysthe instrument reading on the
CRT. The computer must be equipped with a Keithley Instruments
Model 8573 GPIB IEEE interface and the DOS 20 operating system. The
GPIB software and hardware must be configured per the Keithley In-
struments Model 8573 Instruction Manual.

DIRECTIONS
1. Using the rear panel switches set the primary address of the Model
485 to 22 (10110).
2 Wti the power off, connect the Model 485 to the IEEE-488 interface
installed in the IBM computer.
3. Using the interface software IBCONF program, set up the GPIB.COM
handler so that "DEV22" has a primary address of 22 Again, consult
the interface board instruction manual for complete details.
4. Place the instrument software disc in the default drive, type LOAD
"DECL", and press the return key.
5. Enter the following program into the computer, pressing the return
key after each line is typed. Lines l-6 are part of the DECL program
previouslyloaded and naed not be typed in.
6. Run the program and type in the desired command string when
prompted. For example: to place the Modal 485 into the one shot on
talk trigger mode and in the &A range, type in Tl R4X and press the
return key.
7. The display will show the Model 485 reading string on the CRT. For
example: when the Model 485 is in Zero Check, the displaywill read
NDCA + O.OOOOE-6.
8. To exit the program type EXIT and press return.

PROGRAM COMMENTS
1 CLEAR ,160OOl GPIB-PC Rev. B.0
2 IBlNlTl = 160001 IBM BASICA Declaration
File.
3 IBINlT2 = IBlNlTl + 3
4 BLOAD "BIB.M"IBINITl
5 CALL IBINITl(IBFIND,IBTRG,
BCLR,IBPCT,IBSIC,IBLOC,
IBPPC,IBBNA,IBONL,IBRSC,
IBSRE,IBRSV,IBPAD,IBSAD,
IBIST,IBDMA,IBEOS,IBTMO,
IBEOTI
6 CALL IBINITZ(lBGTS,IBCAC,
IBWAIT,IBPOKE,IBWRT,
IBWRTA,IBCMD,IBCMDA,

19
tBRD,WRDA,tBSTOPP.tBRPP.
IBRSP,IBDIAG,IBXTRC.
IBSTA%,IBERR%,IBCNT%f
10 CLS
20 NA$="GfIB9":CALL IBFIND Find the board number.
(NAS,BRW%)
30 NAS = "DEVW:CALL IBFIND Fktd the 485 number.
(NAS,M485%)
40 V% =22CALL IBPAD Change to primary address
Wl85%,V%1 22.
50 V% = 1:CALL IBSRE Set REN true.
(BRDO%,V%)
60 lNPLTT"COMMAND";CMDS Prompt for wmmand
string.
70 IF CMDS="EXIT" THEN 140 See if program is to be
halted.
60 IF CMD$="" THEN 60 If null command string go
back and get another.
90 CALL IBWRT(M485%,CMDS) Address 485 to listen and
sand command string.
100 RDS=SPACE$(BO) Assign reading input buffer.
105 CALL IBRD (M485%, RD91
110 RDS= LEFWRDS,IBCNT%) Trim strfng to proper size
120 PRINT RDS Display the reading on the
CRT
130 GOT0 120 Repeat
140 V% =&CALL IBONL Close the board file.
fM485%,V%)
150 CALL IBONLlM485%,V%l Close the instrument fife.
160 END
NOTE: Lines l-6 of this program need not be typed in. They are con-
tained on the Roppy disc. When the command LOAD"DECL" is
entered, these lines are already there.

NOTE: If conversionto numeric variable is desired, change lines 110 and
120 as follows:
110 RD=VALtMIDStRDS,5,14H
120 PRINT RD

20
APPLE II (APPLE Interface]

The following program obtains one reading from the Model 485 Picoam-
meter and displaysthe reading on th APPLE II screen, using an APPLE
IEEE-488 interface.

DIRECTIONS
1. Using the rear panel switches, set the primary address of the Model
485 to 22 (10110).
2. Connect the Model 485 to the APPLE II and APPLE IEEE-488 inter-
face.
3. Enter the following program using the RETURN key after each line.
4. Type in RUN and depress the RETURN key.
5. The display will read "TEST SETUP".
8. To program the Model 485 to the w range and take a reading type
in R4TlX and depress the RETURN key.
7. The disolavwill read NDCA + O.OOOOE-6 when the Model 485 is in
zeroctL?cic.
PROGRAM COMMENTS
10 DIM A$(2O),BS(20) Dimension data string.
20 ZS = CHRS(28) Terminator
30 INPUYTEST SETUP?";B$ Enter programming command.
Example: 2& range = R4TlX
40 PR#3 Send output to IEEE bus.
50 IN#3 Get input from IEEE bus.
60 PRINT "RA" Turn remote on.
70 PRINT "W-i%"~Z$~B$
r , Write BS to 485.
80 PRINT "LFl" Linefeed On
90 PRINT "RDV".Z$.:INPUT " `I;
, r Read data from 485.
AS
100 PRINT "UT'
110 PR#O Send output to CRT.
120 IN#O Get input from keyboard.
130 PRINT A$
140 GO TO 30 Repeat
NOTE: If conversion to numeric variable is needed, add the following:
134 A=VAL(MIDS(AS,5,111)
136 PRINT A

21
HP-85

The following program obtains ooereadingfromthe W 485 Piwam-
meter and displays the reading on the HP85 CRT scr~-%, using the
62937A GPIB interface and an I/O ROM.

DIRECTIONS
1. Using the rear panel awitches set the primary address on the Model
465 to 22 (10110~.
2. Connect the Model 465 to the HP 62Q37A IEEE interface.
3. Enter the following program using the END LINE k8yaft8r each lineis

4. Depress the RUN key.
5. The display will read "TEST SETUP".
6. To program the Model 465 to the 2@ range and take a reading, type
in R4TlX and depress the END LINE key.
7. The displaywill read NDCA + O.OOOOE--6when the Model 485 is in
Zero Check.

PROGRAM COMMENTS
10 REMOTE 722 Set to remote.
20 DISP `TEST SETUP" Prompt for test setup.
30 INPUT ES
40 OUTPUT722;B$ Prompt the 465.
50 EMER 722;A$ Get data from 485.
60 DISPAS
70 GO TO 20 Repeat
80 END
NOTE: If mnvetion IO numeric variable is needed, change line 60 m
follows:
60 DISP VALLASWI

22
HP 9825A

The following program obtains one reading from the Model 485 Picoam-
meter and displaysthe reading on the HP 9825A using a 98034A HPIB
interface and a 9872A extended I/O ROM.

DlRECTfONS
1. Using the rear panel switches set the primary address of the Model
485 to - l101101.
.-- 22 ..-..-,.
2. Connect the Model 485 to HP 9825A and 98034A HPIB interface.
3. Enter the following program using the STORE key after each line is
typed. Line numbers are automatically assigned by the 9825A.
4. Depress the RUN key.
5. The display will read "TEST SETUP".
6. To program the Model 485 to the w range and tak8 a reading, type
in R4TlX and depress the CONTINUE key.
7. The displavwill read NDCA + O.OOOOE-6 when the Model 485 is in
Zero Check.

PROGRAM COMMENTS
0 dim A$L!O~,B$I201 Dimension data strings.
1 dev"485",722 Define Model 485 address 22.
2 rem"485" Set to remote.
3 ent"TEST SETUP",B$ Enter programming command.
(Example: w range = R4TlX)
4 wrt"485",BS Output program command to
Model 485 via IEEE bus.
5 red'WW,A$ Read data from Model 485 via
IEEE bus.
6 prtA$ Print data on hard copy printer.
7 gto3 Repeat.
NOTE: If conversionto numeric variable is desired, omit line 6 and 7 and
substitute:
8 "e" - A$[13,131;flt5 Convert to numeric variable.
7 prt valtASf51)
8 gto3 Repeat

23
HP 9818

The following program sends a command string to the Model 485
Piwammeter, reads data and displaysthe data on the HP 9816 CRT, us-
ing BASIC 2.0.

DIRECTIONS
1. Using the rear panel switches set the primary address of the Model
485 to 22 (10110).
2. Wnh the power off, connect the Model 485 to the HP 9816 and HP
82937A GPIB interface.
3. Type EDIT and press the EXEC key.
4. Enter the following program using the ENTER key after each line is

5. Press the HP 9815 RUN key.
6. The display will read `TEST SETUP".
7. To program the Model 485 to the &A range and to take a reading
tvDe in R4X and press the ENTER kev.
8. The displaywill r&d NDCA t O.OOObE-6 when the Model 485 is in
Zero Check.

PROGRAM COMMENTS
10 REMOTE 722 Set to remote.
20 INPUT'I-EST SETUP" A$ Prompt for test setup,
30 OUTPUT 722; AS ' Send command string to 485.
40 ENTER 722;B4 Get data string from 485.
50 PRINT BS Display data string.
60 GOT020 Repeat
70 END
NOTE: If mnversion to numeric variable is desired, change lines 40 and
50 as follows:
40 ENTER 722;B
50 PRtNTB

24
HP 98458

The following program obtains one reading from the Model 485 Picoam-
meter and displays the reading on the 98458 screen using a 98034A
HPIB interface and an I/O ROM.

DIRECTIONS
1. Using the rear panel switches set the primary address of the Model
485 to 22 IlOllO).
2. Connect the Model 485 to the HP 98458 and the 98034A interface.
3. Enter the following program using the STORE key after each line.
4. Depress the RUN key.
5. The display will read "TEST SETUP" in the lower left comer.
6. To program the Model 485 to the 2~& range and take a reading type
in R4TlX and press the EXECUTE key.
7. The display will read NDCA + 0.0000E-6 when the Model 485 is in
Zero Check.

PROGRAM COMMENTS
10 DIM ASI201, B$lZOl
20 E485 = 722 Define Model 485 address 22.
30 INPLF'TEST SEWP",B$ Enter programming command
(Example: 2$1 rang8 = R4TlX).
40 OUTPUT E485;B$ Output program command to Model
485 via IEEE bus.
50 ENTER W35;A9 Read data from 485 via IEEE bus.
60 PRINT A$ Print data on 98458 CRT.
70 GO TO 30 Repeat
NOTE: If conversion to numeric variable is desired, omit line 60 and
substitute:
60 PRINT VAL(A$IB,lll) Convert string to numeric value.
70 GO TO 30 Repeat

25
TEK 4052

The f&owing program obtains one reading from the Model 485 Picoam-
meter and displaysthe reading on the TEK 4052 graphics terminal, with
a 4051 GPIB interface.

DIRECTIONS
1. Using the tear panel swltchas set the primary address of the Model
485 to 22 (101IOi.
2 Connect the Model 485 to the TEK 4051 IEEE interface.
3. Enter the following program using the RETURN key after each line.
4. Type in RUN.
5. The display will read "TEST SETUP".
6. To program the Model 485 to the 2+A range and take a reading, type
in R4TlX and press the RETURN key.
7. The display wiil read NDCA f O.OlWOE-6 when the Model 485 is in
Zero Check.

PROGRAM COMMENTS
5 PRINT @ 37,o: IO, 255, I3
IO PRINT "TEST SETUP" Prompt for the test setup.
20 PRINT B$
30 PRINT @ 22: BS Program the Model 485.
40 INPUT % 22: AS Get data from the Model 485.
50 PRINT AS
60 GOT010 Repeat
NOTE: If conversion to numeric variable is desired, change lines 40 and
!XtO:
40 INPUT % 22: A
80 PRINT A

26
DEC LSI 11

The following program obtains one reading from the Model 485 Picoam-
meter and displaysthe reading on the DEC LSI 11 microcomputer CRT
terminal. The LSl 11 must be confiaured with 16k words of RAM and an
IBV 11 IEEE interface. The softw&e must be configured with IB soft-
ware as well as the FORTRAN and the RT 11 operating system.

DIRECTIONS
1. Using the rear panel switches set the primary address on the Model
485 to 22 f10110).
2. Connect the Model 485 to the IBV 11 IEEE cable.
3. Enter the following program, using the editor under RT 11 and the
name IPHILD.
4. Compile using the fortran compiler as follows: FORTRAN IPHILD.
5. Link with the svstem and IB librariesas follows: LINK IPHILD,IBLIB.
6. Type RUN IPHILD and depress the RETURN key.
7. The disolav will read "ENTER ADDRESS".
8. Type in'iand depress the RETURN key.
9. The display will read "TEST SETUP".
10. To program the Model 485 to the &A range and take a reading, type
in R4TlX and depress the RETURN key.
11. The displaywill read NDCA + O.OOOOE-6 when the Model 485 is in
Zero Check.

PROGRAM COMMENTS
INTEGER*2 PRIADR
LOGlCAL*1MSGf80),INPUT63O)
DO 2 I = 1,lO
CALL IBSTERfI,O) ITurn off IB errors.
2 CONTINUE
CALL IBSTER (15,5) IAllow 5 errors 16's.
CALL IBTlMO (120) IAllow 1 second bus
timeout.
CALL IBTERM ("10) IS& LF as terminator.
CALL IBREN ITurn remote on.
4 TYPE5
5 FORMAT flX,`ENTER llnput the address 22.
ADDRESS',81 ACCEPT
10, PRIADR
10 FORMAT (2141
12 TYPE 15
15 FORMAT flX,`TEST SETUP',$) [Prompt for the test setup.
CALL GETSTR (5,MSG,72l IGet the test setup.
CALL IBSEOI (MSG.-l PRIADR) [Program the 485.

27
18 I = IBRECV (\NPUT,BO.PRlADR,
INPUT II + 1) = 0
CALL PUTSTR 0 \NPUT `07
CALL IBUNT ' ' Wntalk the 485.
GOT012 IRepeat
END

28
PET/CBM 2001

The following program obtains one reading from the Model 465 Picoam-
mater and displays the reading on the PET/CBM 2001 screen.

DIRECTIONS
1. Using the rear panel switches sat the primary address of the Model
465 to 22 f10110).
2. Connect the Model 465 to the PET/CBM 2001 IEEE interface.
3. Enter the following program using the RETLtRN key after each line.
4. Type RUN and depress the RETURN key.
5. The display will read "TEST SETUP".
6. To program the Model 465 to the 2& range and take e reading, type
in R4TlX and depress the RETURN key.
7. The displaywill read NDCA + O.OOOOE-6 when the Model 485 is in
Zero Check.

PROGRAM COMMENTS
10 OPEN 622 Open file 6, primary address 22.
20 INPUT "TEST SETUp";BS Enter programming command.
(Example: w range = R4TlX).
30 PRINT&B$ Output to IEEE bus.
40 INPUT#G,A$ Read data from Model 485 via IEEE
bus.
50 IFST = 2THEN40 If time out, input again.
60 PRINT A$ Print data.
70 GOT020 Repeat
NOTE: If conversionto numeric variableis desired, omit line 70 and type
:
the following:
70 A = VAL(MID$fAS,5,15)) Convert to numerfc variable.

60 PRINT "A="
90 GOT020 '
.A Repeat

29
E-H 7000 COMPUTER

The following program sends a data string from the E-H computer to the
Modei 485 Picoammeter and then displaysthe instrument reading on
the computer CRT. The hH 7000 must be configured with MS-DOS
and BASICA as outlined in its instruction manual.

DIRECTIONS
1. Using ffie rear panel switches set the primary address of the Model
485 to 22 (10110).
2. With the power off, connect the Model 485 to PORT 1 of the com-
puter.
3. While in BASICA, type LOAD "EHE488.CMP" to Load the GPIB
handler software.
4. Add the lines below to the front of the program now [n memory;
press the return key after each line is typed. The complete program
including the GPIB handler software may now be saved in the usual
manner.
5. Press the computer F2 key to run the program. The CRT will prompt
with COMMAND?.
6. TVpe in the desired command. For example: To program the instru-
ment to the w range and take a reading, type in R4TIX and press
the return key.
7. The computer CRT will then display the instrument's data string on
the CRT. For example: with the Model 485 on the w range and with
Zero Check enabled, the data string reads NDCA f O.OOOOE-6.

PROGRAM COMMENTS
10 CLS
20 GOSUB 65010 `Initializehandler software.
30 CALL PORT1 `Initialize Port 1.
40 CALL INIT `Initializeinterface.
50 DEV$="22" `Primary address = 22.
60 INPUT "COMMAND'CG `Prompt for command string.
70 IF C$ = " " THEN sd `If null input go back.
80 INS = SPACES 120) `Define reading buffer.
90 CALL SNDSTRlDEVS,C$) `Send command string to 4135.
100 CALL RCVSTR(DEV$,INS) `Get reading from 485.
110 PRlNT INS `Display reading string on CRT.
120 GO TO 60 `Repeat
NOTE: For conversion to numeric variable, change line 110 to:
110 PRINT VALfMIDS(tN$,5,152))

30
Test Instrumentation Group
28775 Aurora Road /Cleveland, Ohio 44139

◦ Jabse Service Manual Search 2024 ◦ Jabse Pravopis ◦ onTap.bg ◦ Other service manual resources online : Fixya ◦ eServiceinfo