Changes for page Testing Procedures

Last modified by robert on 2024/12/09 16:08

From 3.1 to 2.1 From 7.2 to 7.1

From version 7.1

edited by robert
on 2024/12/03 11:49

Change comment: There is no comment for this version

To version 3.1

edited by robert
on 2024/12/02 13:14

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- 1733178329484-829.png

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@@ -50,7 +50,7 @@
  * Insert SD card and verify the latching mechanism holds the card and releases it.
  * Verify the SD card is detected and can be erased.
--=== System information ===
++=== System information  ===
  Record the Firmware version.
@@ -59,7 +59,7 @@
  == Functional Test ==
--=== Charging ===
++=== Charging  ===
  Verify the battery is charging (LPR differs from TSAWR, additionally, TSAWRs differ between each other based on firmware version).
@@ -85,7 +85,7 @@
  If the user requires to verify the sensor or the validity of the recorded data, a power spectral density analysis would need to be performed, see rest of document (link here) for instructions on how to perform this test.
  )))
--=== Recording test ===
++=== Recording test  ===
  Insert SD card and erase the content.
@@ -200,7 +200,8 @@
  * Alternatively the SD card may be faulty and need to be replaced
  )))
--(% class="table-condensed" style="width:888px" %)
++
++(% style="width:888px" %)
  |(% colspan="2" style="width:885px" %)(((
  **Error Screen Warnings **
  )))
@@ -295,7 +295,9 @@
  * Alternatively the SD card may be faulty and need to be replaced
  )))
--(% class="table-condensed" style="width:1063px" %)
++
++
++(% style="width:1063px" %)
  |(% colspan="2" style="width:1060px" %)(((
  **General System Errors **
  )))
@@ -345,7 +345,7 @@
  * Restart or try an alternative unit
  )))
--(% class="table-condensed" style="width:1066px" %)
++(% style="width:1066px" %)
  |(% colspan="2" style="width:1063px" %)(((
  **Battery Errors **
  )))
@@ -411,7 +411,9 @@
  * There is a damaged cell which will need to be replaced
  )))
--(% class="table-condensed" style="width:1064px" %)
++
++
++(% class="table-bordered" style="width:1064px" %)
  |(% colspan="2" style="width:1061px" %)(((
  **Hardware Errors **
  )))
@@ -446,6 +446,7 @@
  * Reformat the card (FAT32)
  )))
++
  = Sensors =
  Sensors can be tested in many ways...
@@ -452,40 +452,8 @@
  == ... via Centaur (Nanometrics sensors) ==
--//(originally written by F. Bozinovic May 2024)//
++GUIDE TO TEST VIA CENTAUR
--=== Process ===
--
--The Centaur data recorder can generate and output an analog signal using a 16-bit internal digital-to analog converter (DAC). The DAC output is applied to the sensor for calibration purposes via the matching sensor cable. Make sure to use manufacturer cables as the correct signal lines have been connected to the correct pins of the mating connector. The Centaur CTR, CTR2 and CTR3 series models may generate signals of up to ±5 V amplitude, while the Centaur CTR4 series models have an enhanced calibration output.
--
--Calibration output signal actions are launched from the Waveform page in the Centaur Web interface. A synthetic waveform signal generator allows you to generate sinewave and pseudo-random binary (PRB) signals on demand. User can configure the sine frequency or PRB pulse width, signal duration and amplitude as well as specify lead-in and lead-out silence intervals before and after the calibration waveform. One can also select and play a calibration file containing any other desired digital time series waveform that by uploading it to the Centaur, such as a swept sinewave, step function, random noise, or chained PRB sequence.
--
--The following sample calibration files are supplied with the Centaur. These files may be used to visually verify functionality and approximate sensitivity of the sensor by inspection of the output waveform:
--
--* **sine_5V_30s** generates a 1 Hz sine wave with 5 V amplitude lasting 30 seconds.
--* **step_0V_to_5V_15s** generates a 0 V signal for 15 seconds followed by a positive 5 V step function lasting 15 seconds.
--* **prb 1V 20ms 10min** generates a 10 minute PRB sequence using 20 ms pulses and 1 V amplitude.
--* **prb 1V 5s 150min** generates a 2.5 hour PRB sequence using 5 second pulses and 1 V amplitude.
--* **prb 2V 5s 8hr** generates an 8 hour PRB sequence using 5 s pulses and 2 V amplitude.
--
--=== Procedure ===
--
--1. Log-in to the Centaur Web Interface and use the Admin credentials
--1. Navigate to the Health page and verify that the sensor is properly levelled and recognised by its serial number.
--1. To configure the calibration parameters, navigate to the Waveform page.
--1. From the Calibration panel at the top page, select Type from the drop-down list and  choose Sine.
--1. For the CTR4 series models, additional option to select between Voltage or Current is available.
--1. Click on the Configure button to access the calibration dialog box for the selected Playback.
--1. Configure the signal characteristics by selecting 5V, 30 sec with gain of 1.
--1. Configure the padding before and after the calibration signal, enter 5 seconds.
--1. The Duration (s) time can be made shorter or longer as required by user. NOTE, for shorter frequencies a longer duration will be required for the signal to complete its full cycle and to capture the entire waveform on the screen.
--1. Click OK button to close the dialog box and save the settings.
--1. Click the start calibration button  [[image:1733178329484-829.png]] to begin the process. Approximately 5 seconds of time padding ( as set in Step 8) will past before the sensor responds to the injected signal and display the sine wave feedback response.
--1. The calibration will end after 30 seconds (as set in Step 7) or can be terminated manually by pressing the stop button. The calibration will then stop after 5 seconds and any configured lead out silence will be skipped.
--1. Click on the pause button on the bottom of the page to stop the live stream and use the arrows to centre the sine signal response. Note that the screen waveform will turn Blue and the stream will freeze. Avoid capturing live streaming signal!
--1. Once the response signal is cantered, perform a screen-capture “Print Screen” button or use “Snippet” tool and save the captured image locally. In the nametag, include a Serial number, date and sensor type.
--1. Archive and back-up the file.
--
  == ... via data comparision (vs S1.AUANU) ==
  CODE & Guide to use code
@@ -499,20 +499,23 @@
  This procedure describes the method for testing solar panels and determining how to identify defective panels. The testing of solar panels should be performed outdoors, under bring sun to obtain accurate results.
--(% class="box warningmessage" %)
--(((
--DO NOT test solar panels indoors using room lighting, this does not provide adequate light energy and will not give reliable results.
--)))
++**DO NOT test solar panels indoors using room lighting, this does not provide adequate light energy and will not give reliable results. **
  Following materials are required
  * Solar panel for testing
++
  * Digital multi-meter (DMM)
++
  * Load Resistor (designated power resistor of known value)
++
  * Wire leads
++
  * Alligator clips
++
  * Spreadsheet with formulae
++
  * Marker/ pen
  Test Method
@@ -536,11 +536,11 @@
--(% class="table-bordered" style="height:563px; width:433px" %)
++(% style="height:563px; width:433px" %)
  |(% style="width:148px" %)(((
  Solar panel ID#
  )))|(% style="width:281px" %)(((
--Measurement
++
  )))
  |(% style="width:148px" %)(((
  Voltage (Voc)
@@ -598,13 +598,11 @@
  Load resistor value
  )))
++
  For cells in rows (Solar panel #ID), (Voc), (Ioc), (Vrl), enter the recorded values.
--(% class="box warningmessage" %)
--(((
--These values should be measured and NOT taken from the panel specification sticker. The values may appear same or similar but these are manufacturer factory values obtained under very strict control conditions.
--)))
++**These values should be measured and NOT taken from the panel specification sticker. The values may appear same or similar but these are manufacturer factory values obtained under very strict control conditions. **
  (Rload) cell is the Load Resistor value. This cell is a constant and does not need to be copied for all entries.
@@ -612,25 +612,25 @@
  Inside the “Vrl (Theoretical)” cell enter the following formula using the corresponding cells.
--V_{RL}=I_{oc}\times R_L
++[Equation]
  Inside the “Rated Power” cell enter the following formula using the corresponding cells.
--P_{oc}=V_{oc}\times I_{oc}
++[Equation]
  Inside the “Load Power” cell enter the following formula using the corresponding cells.
--P_{RL}=\frac{V_{RL}}{R_L}\times V_{oc}
++[Equation]
  Inside the “Power Loss %” cell enter the following formula using the corresponding cells.
--The calculated values that are negative represent power loss, and positive values are power gain. Performing “conditional formatting” on these cells with colour gradient (defined by colour break limits) would yield visually easy to recognise defective panels.
++The calculated values that are negative represent power loss, and positive values are power gain. Performing “conditional formatting” on these cells with colour gradient (defined by colour break limits) would yield visually easy to recognise defective panels.
--Power\ Loss\ \%=\frac{P_{RL}}{P_{oc}}\times 100-100
++[Equation]
  Perform all the calculations for each solar panel ID entered.

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