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11.. . A
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OMP-MODL
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Memory:
Three selections are available for utilization of the OMP-MODL memory:
Log to Full Memory and STOP Processing
- if selected, the OMP-MODL
will log data until memory is filled, then stop execution of the Program Net
and go into a low power sleep mode.
NOTE: If MILLISECOND Sample Clock Resolution is selected (see below)
logging sessions must be limited to a maximum length of 40 days.
Log to Full Memory and CONTINUE Processing
- if selected, the OMP-
MODL will log data until memory is filled, then continue the execution of
the Program Net excluding the storage of data to memory. This mode
allows all of the non-Memory icons in the Program Net to continue
operation providing continued Alarm, Probe Point, etc access.
NOTE: If MILLISECOND Sample Clock Resolution is selected (see below)
memory must be filled before a maximum of 40 days after Enabling the
OMP-MODL . Processing will continue after the 40 day limitation.
Rotary Memory
- if selected, the OMP-MODL will log data until the
memory is filled, then begin overwriting the oldest sample in memory.
Processing of the complete Program Net will continue as normal.
NOTE: If MILLISECOND Sample Clock Resolution is selected (see below)
logging sessions must be limited to a maximum length of 40 days.
Sample Clock Resolution:
Two options are available for selecting the time
resolution of the OMP-MODL.
SECONDS
- This mode should be used for all Program Nets that have
Sample Rate Clocks set at 1 second or slower. In this mode, the OMP-
MODL `sleeps’ in a low-power mode during times of inactivity, providing
extended battery life. Sample Rate Clocks can be set as fast as 1 second.
MILLISECONDS
- This mode must be used if any Sample Rate Clocks will
be set at faster than 1 second rates. In this mode, the OMP-MODL can
resolve time increments as small as 1/1000 of a second.
NOTE:
Use of the
millisecond mode will result in higher power consumption as the OMP-
MODL microprocessor is continually operating. Depending on the Program
Net, the energy consumption in this mode may be approximately 10 to 15
times higher than in the SECOND mode.
NOTE:
In MILLISECOND Mode, logging sessions must be
limited to a maximum length of 40 days. This limitation
holds for both Rotary and Log to Full Memory modes.
This 40 day limit is due to a maximum time count that the
OMP-MODL can internally store at the faster clock rate.
For sessions longer than 40 days, utilize the SECOND
mode.
Recalibration Period:
The OMP-MODL performs various self-calibrations during
execution of a Program Net. The User can specify the frequency of these
calibrations. If a 0 is entered for the period, a recalibration will be
performed at the start of each Program Net execution. If speed is not of
concern, entering 0 for each of the recalibration periods will result in
optimum performance.
ADC
- the analog to digital converter used within the OMP-MODL and
much of the analog circuitry incorporated into Interface Modules can drift
over time and temperature fluctuations. By performing a recalibration,
most of this drift can be nulled. Specify the period in seconds between
recalibrations.
Summary of Contents for OMP-MODL
Page 1: ......
Page 9: ...1 INTRODUCTION USING THE MODULOGGER 1 7 13 ...
Page 23: ...2 OMP MODL System Base Using the OMP MODL 2 14 NOTES ...
Page 24: ...2 ModuLogger System Base Using the ModuLogger 2 1 ...
Page 30: ...3 INTERFACE MODULES USING THE OMP MODL 3 6 NOTES ...
Page 70: ...3 INTERFACE MODULES USING THE OMP MODL 3 46 NOTES ...
Page 76: ...3 INTERFACE MODULES USING THE OMP MODL 3 52 NOTES ...
Page 82: ...3 INTERFACE MODULES USING THE OMP MODL 3 58 NOTES ...
Page 83: ...3 INTERFACE MODULES USING THE MODULOGGER 3 1 ...
Page 105: ...5 HYPERCOMM COMMUNICATIONS USING THE OMP MODL 5 18 NOTES ...
Page 106: ...5 HYPERCOMM COMMUNICATIONS USING THE MODULOGGER 5 1 ...
Page 117: ...6 PCMCIA CARD CONFIGURATION AND USE USING THE MODULOGGER 6 1 ...
Page 134: ...7 HYPERNET ICON BASED PROGRAMMING USING THE OMP MODL 7 17 NOTES ...
Page 141: ...8 P P C D U OMP MODL ...
Page 149: ...9 HYPERPLOT GRAPHIC DATA DISPLAY USING THE OMP MODL 9 8 ...
Page 161: ...10 HYPERTRACK REAL TIME DATA DISPLAY USING THE OMP MODL 10 12 NOTES ...
Page 162: ...10 HYPERTRACK REAL TIME DATA DISPLAY USING THE OMP MODL 10 1 ...
Page 163: ...11 APPENDICES USING THE OMP MODL 11 1 11 APPENDICES ...
Page 164: ...11 APPENDICES USING THE OMP MODL 11 2 NOTES ...
Page 270: ...11 APPENDIX A MASTER ICON FILE REFERENCE USING THE OMP MODL 11 108 ...
Page 276: ...11 APPENDIX C HYPERWARE FILE LISTING USING THE OMP MODL 11 114 NOTES ...
Page 278: ...11 APPENDIX C HYPERWARE FILE LISTING USING THE OMP MODL 11 116 NOTES ...
Page 279: ......
Page 282: ...11 APPENDIX E CHANGING THE OMP MODL EPROM USING THE OMP MODL 11 120 NOTES ...
Page 288: ...11 APPENDIX G HYPERNET THEORY OF OPERATION USING THE OMP MODL 11 126 NOTES ...
Page 290: ...11 APPENDIX I RS 232 CABLE PORT AND ADAPTER USING THE OMP MODL 11 128 NOTES ...
Page 297: ...11 APPENDIX K MODEM CONFIGURATION USING THE OMP MODL 11 135 ...