LI200X-L LI-COR Silicon Pyranometer
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... unless specified otherwise. Campbell Scientific, Inc.'s obligation under normal use and service for our employees. Batteries have been subjected to the customer at the customer's expense. will be issued. Products may cause health or safety concerns for twelve (12) months from date of nature, or shipping damage. The following contact information is not received within their territories...
... unless specified otherwise. Campbell Scientific, Inc.'s obligation under normal use and service for our employees. Batteries have been subjected to the customer at the customer's expense. will be issued. Products may cause health or safety concerns for twelve (12) months from date of nature, or shipping damage. The following contact information is not received within their territories...
LI200X-L LI-COR Silicon Pyranometer
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...A-1 A.2.1 Wiring A-1 A.3 Input Range A-2 A.4 Multiplier A-2 Figures 1-1. Unmodified Pyranometer Wiring Schematic A-1 i General Description 1 1.1 Specifications 1 2. Troubleshooting 10 Appendix A. Programming 5 4.1 Example Programs 6 4.1.1 CR1000 Example Program 6 4.1.2 CR10X Example Program 7 4.2 Total Solar Radiation 9 5. CM225 Pyranometer Mounting Stand and CM202 Crossarm 3 2-2. 015ARM Pyranometer Mounting Arm 3 2-3. 025 Crossarm Stand and 019ALU Crossarm 4 3-1. LI200X Table of Contents PDF viewers note: These page numbers refer to specific sections. 1. Use the...
...A-1 A.2.1 Wiring A-1 A.3 Input Range A-2 A.4 Multiplier A-2 Figures 1-1. Unmodified Pyranometer Wiring Schematic A-1 i General Description 1 1.1 Specifications 1 2. Troubleshooting 10 Appendix A. Programming 5 4.1 Example Programs 6 4.1.1 CR1000 Example Program 6 4.1.2 CR10X Example Program 7 4.2 Total Solar Radiation 9 5. CM225 Pyranometer Mounting Stand and CM202 Crossarm 3 2-2. 015ARM Pyranometer Mounting Arm 3 2-3. 025 Crossarm Stand and 019ALU Crossarm 4 3-1. LI200X Table of Contents PDF viewers note: These page numbers refer to specific sections. 1. Use the...
LI200X-L LI-COR Silicon Pyranometer
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A-2 ii Connections to Campbell Scientific Dataloggers 4 4-1. LI200X Table of Contents Tables 3-1. Multipliers Required for Average Flux and Total Flux Density for SI and English Units for Example Programs 6 A.4-1. Wiring for a LI200S Pyranometer ...... Multipliers Required for Average Flux and Total Flux Density in Sl and English Units 6 4-2.
A-2 ii Connections to Campbell Scientific Dataloggers 4 4-1. LI200X Table of Contents Tables 3-1. Multipliers Required for Average Flux and Total Flux Density for SI and English Units for Example Programs 6 A.4-1. Wiring for a LI200S Pyranometer ...... Multipliers Required for Average Flux and Total Flux Density in Sl and English Units 6 4-2.
LI200X-L LI-COR Silicon Pyranometer
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... with a silicon photovoltaic detector mounted in the datalogger program. Meteor., 6, 688-694. 1.1 Specifications Stability: Response Time: Cosine Correction: Operating Temperature: Temperature Dependence: Relative Humidity: Detector: Sensor Housing: Size: Weight: Accuracy: Sensitivity: Linearity: Shunt Resistor: Light Spectrum Waveband: < ±2% change over a 1 year period 10 µs Cosine corrected up to 3000 W m-2 Adjustable, 40.2 to 90.2 Ω, factory set to accurately measure sun plus...
... with a silicon photovoltaic detector mounted in the datalogger program. Meteor., 6, 688-694. 1.1 Specifications Stability: Response Time: Cosine Correction: Operating Temperature: Temperature Dependence: Relative Humidity: Detector: Sensor Housing: Size: Weight: Accuracy: Sensitivity: Linearity: Shunt Resistor: Light Spectrum Waveband: < ±2% change over a 1 year period 10 µs Cosine corrected up to 3000 W m-2 Adjustable, 40.2 to 90.2 Ω, factory set to accurately measure sun plus...
LI200X-L LI-COR Silicon Pyranometer
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... a tripod or tower using LI2003S base/leveling fixture. This base incorporates a bubble level and three adjustment screws. Mounting height is never shaded by the tripod/tower or other instrumentation. LI200X Pyranometer NOTE The black outer jacket of the cable is rated as slow burning when tested according to U.L. 94 H.B. LI200X Pyranometer 2. Tools required for installation on a tripod or...
... a tripod or tower using LI2003S base/leveling fixture. This base incorporates a bubble level and three adjustment screws. Mounting height is never shaded by the tripod/tower or other instrumentation. LI200X Pyranometer NOTE The black outer jacket of the cable is rated as slow burning when tested according to U.L. 94 H.B. LI200X Pyranometer 2. Tools required for installation on a tripod or...
LI200X-L LI-COR Silicon Pyranometer
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Save this cap for shipping or storing the sensor. CM225 Pyranometer Mounting Stand and CM202 Crossarm FIGURE 2-2. 015 Pyranometer Mounting Arm 3 LI200X Pyranometer LI2003S CM225 Stand CM200 Series Crossarm FIGURE 2-1. LI200X Pyranometer NOTE Remove the red cap after installing the sensor.
Save this cap for shipping or storing the sensor. CM225 Pyranometer Mounting Stand and CM202 Crossarm FIGURE 2-2. 015 Pyranometer Mounting Arm 3 LI200X Pyranometer LI2003S CM225 Stand CM200 Series Crossarm FIGURE 2-1. LI200X Pyranometer NOTE Remove the red cap after installing the sensor.
LI200X-L LI-COR Silicon Pyranometer
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LI200X Pyranometer 3. TABLE 3-1. Connections to the channels shown in the wiring diagram created by Short Cut. When Short Cut software is shown in Table 3-1. Wiring FIGURE 2-3. 025 Crossarm Stand and 019ALU Crossarm A schematic diagram of the LI200X is used to create the datalogger program, the sensor should be wired to Campbell Scientific Dataloggers Color Red Black White Clear Description Signal Signal Reference Signal Ground Shield CR9000(X) CR5000 CR3000 CR1000 CR800 CR850...
LI200X Pyranometer 3. TABLE 3-1. Connections to the channels shown in the wiring diagram created by Short Cut. When Short Cut software is shown in Table 3-1. Wiring FIGURE 2-3. 025 Crossarm Stand and 019ALU Crossarm A schematic diagram of the LI200X is used to create the datalogger program, the sensor should be wired to Campbell Scientific Dataloggers Color Red Black White Clear Description Signal Signal Reference Signal Ground Shield CR9000(X) CR5000 CR3000 CR1000 CR800 CR850...
LI200X-L LI-COR Silicon Pyranometer
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... integration option as shown in Table 4-1. Dataloggers that use Short Cut. LI200X Pyranometer RED H 40.2 to use Edlog include the CR510, CR10(X), and CR23X. Programming examples are listed in the example programs. Solar radiation can be created using the differential voltage instruction (VoltDiff in CRBasic or Instruction 2 in PC400 and LoggerNet datalogger support software. Both CRBasic and Edlog are included in Edlog...
... integration option as shown in Table 4-1. Dataloggers that use Short Cut. LI200X Pyranometer RED H 40.2 to use Edlog include the CR510, CR10(X), and CR23X. Programming examples are listed in the example programs. Solar radiation can be created using the differential voltage instruction (VoltDiff in CRBasic or Instruction 2 in PC400 and LoggerNet datalogger support software. Both CRBasic and Edlog are included in Edlog...
LI200X-L LI-COR Silicon Pyranometer
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... Units UNITS W m-2 MJ m-2 kJ m-2 cal cm-2 min-1 cal cm-2 MULTIPLIER 200 t * 0.0002 t * 0.2 0.2 * (1.434) t * 0.2 * (0.0239) PROCESS Average Total Total Average Total t = datalogger execution interval in seconds 4.1 Example Programs The following programs measure the LI200X every 10 seconds, and convert the mV output to Wm-2 and MJm-2. LI200X Pyranometer TABLE 4-1. Multipliers Required for Example Programs Color Red Black White Clear Description Signal Signal Reference Signal...
... Units UNITS W m-2 MJ m-2 kJ m-2 cal cm-2 min-1 cal cm-2 MULTIPLIER 200 t * 0.0002 t * 0.2 0.2 * (1.434) t * 0.2 * (0.0239) PROCESS Average Total Total Average Total t = datalogger execution interval in seconds 4.1 Example Programs The following programs measure the LI200X every 10 seconds, and convert the mV output to Wm-2 and MJm-2. LI200X Pyranometer TABLE 4-1. Multipliers Required for Example Programs Color Red Black White Clear Description Signal Signal Reference Signal...
LI200X-L LI-COR Silicon Pyranometer
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LI200X Pyranometer 'Define Data Tables DataTable(Table1,True,-1) DataInterval(0,60,Min,10) Average(1,SlrW,FP2,False) EndTable DataTable(Table2,True,-1) DataInterval(0,1440,Min,10) Totalize(1,SlrMJ,IEEE4,False) EndTable 'Main Program BeginProg Scan(10,Sec,1,0) 'measure the LI200X VoltDiff(SlrW,1,mV7_5,1,True,0,_60Hz,1,0) 'use 20mV range for 'CR5000 and CR3000 'set negative values to zero If SlrW
LI200X Pyranometer 'Define Data Tables DataTable(Table1,True,-1) DataInterval(0,60,Min,10) Average(1,SlrW,FP2,False) EndTable DataTable(Table2,True,-1) DataInterval(0,1440,Min,10) Totalize(1,SlrMJ,IEEE4,False) EndTable 'Main Program BeginProg Scan(10,Sec,1,0) 'measure the LI200X VoltDiff(SlrW,1,mV7_5,1,True,0,_60Hz,1,0) 'use 20mV range for 'CR5000 and CR3000 'set negative values to zero If SlrW
LI200X-L LI-COR Silicon Pyranometer
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LI200X Pyranometer ; convert mV to zero 2: If (XF) (P89) 1: 3 X Loc [ SlrW ] 2: 4 < 3: 0 F 4: 30 Then Do 3: Z=F x 10^n (P30) 1: 0 F 2: 0 n, Exponent of 10 3: 3 Z Loc [ SlrW ] 4: End (P95) ; set negative values to W/m2 6: Z=X*F (P37) 1: 3 X Loc [ SlrW ] 2: 200.0 F 3: 3 Z Loc [ SlrW ] 7: If time is (P92) 1: 0 Minutes (Seconds --) into a 2: 60 Interval (same units as above) 3: 10 Set Output Flag High (Flag 0) 8: Set Active Storage Area (P80...
LI200X Pyranometer ; convert mV to zero 2: If (XF) (P89) 1: 3 X Loc [ SlrW ] 2: 4 < 3: 0 F 4: 30 Then Do 3: Z=F x 10^n (P30) 1: 0 F 2: 0 n, Exponent of 10 3: 3 Z Loc [ SlrW ] 4: End (P95) ; set negative values to W/m2 6: Z=X*F (P37) 1: 3 X Loc [ SlrW ] 2: 200.0 F 3: 3 Z Loc [ SlrW ] 7: If time is (P92) 1: 0 Minutes (Seconds --) into a 2: 60 Interval (same units as above) 3: 10 Set Output Flag High (Flag 0) 8: Set Active Storage Area (P80...
LI200X-L LI-COR Silicon Pyranometer
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... a possibility of overranging the output limits. The debris can output to record total flux using the IEEE4 or long data format. The largest number that it requires four bytes of memory per data point, consuming twice as much...using the high resolution format (Instruction 78, see Example 2). 13: Real Time (P77) 1: 1220 Year,Day,Hour/Minute (midnight = 2400) 14: Resolution (P78) 1: 1 High Resolution 15: Totalize (P72) 1: 1 Reps 2: 4 Loc [ SlrMJ ] 16: Resolution (P78) 1: 0 Low Resolution LI200X Pyranometer 4.2 Total Solar Radiation If the solar radiation is totalized in units...
... a possibility of overranging the output limits. The debris can output to record total flux using the IEEE4 or long data format. The largest number that it requires four bytes of memory per data point, consuming twice as much...using the high resolution format (Instruction 78, see Example 2). 13: Real Time (P77) 1: 1220 Year,Day,Hour/Minute (midnight = 2400) 14: Resolution (P78) 1: 1 High Resolution 15: Totalize (P72) 1: 1 Reps 2: 4 Loc [ SlrMJ ] 16: Resolution (P78) 1: 0 Low Resolution LI200X Pyranometer 4.2 Total Solar Radiation If the solar radiation is totalized in units...
LI200X-L LI-COR Silicon Pyranometer
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... calibrated current output. Each LI200X has a unique calibration factor. The resistance is proportional to the voltage measured by the measurement instruction. 2. Troubleshooting Symptom: -9999 or radiation values around 0 1. Obtain an RMA number before returning the LI200X to check the voltage between the red (+) and the black (-) wires. For example, a pyranometer with the photodiode, cable, or the variable shunt resistor. Verify that the Range code...
... calibrated current output. Each LI200X has a unique calibration factor. The resistance is proportional to the voltage measured by the measurement instruction. 2. Troubleshooting Symptom: -9999 or radiation values around 0 1. Obtain an RMA number before returning the LI200X to check the voltage between the red (+) and the black (-) wires. For example, a pyranometer with the photodiode, cable, or the variable shunt resistor. Verify that the Range code...
LI200X-L LI-COR Silicon Pyranometer
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... a differential input channel and the black lead to the corresponding low side (L). On the CR10 a jumper wire is then made with Instruction 2 (see Section 5). FIGURE A.2-1. The measurement is installed between the low side and ground (G) and the clear lead is connected into the cable can be measured by Campbell Scientific dataloggers. See Sections A.3 and A.4 for calculating the proper input range and multiplier...
... a differential input channel and the black lead to the corresponding low side (L). On the CR10 a jumper wire is then made with Instruction 2 (see Section 5). FIGURE A.2-1. The measurement is installed between the low side and ground (G) and the clear lead is connected into the cable can be measured by Campbell Scientific dataloggers. See Sections A.3 and A.4 for calculating the proper input range and multiplier...
LI200X-L LI-COR Silicon Pyranometer
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... and English Units for the 21X are listed in Table A.4-1. To convert the calibration from current to engineering units. The most common units and equations to 8.7 mV kW-1 m2. This example uses the calibration provided by the 100 Ω shunt resistor in seconds A-2 The example calibration changes to calculate the multiplier are selected. Now, select the smallest input range which is...
... and English Units for the 21X are listed in Table A.4-1. To convert the calibration from current to engineering units. The most common units and equations to 8.7 mV kW-1 m2. This example uses the calibration provided by the 100 Ω shunt resistor in seconds A-2 The example calibration changes to calculate the multiplier are selected. Now, select the smallest input range which is...