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ea-ps_2084-03b [2015/05/27 18:45] – [mutli-meter] kingkevinea-ps_2084-03b [2024/01/07 17:49] (current) – external edit 127.0.0.1
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   * set voltage and current: in 0.1 V and 0.01 A steps   * set voltage and current: in 0.1 V and 0.01 A steps
   * wide voltage range (0-50 V): 0-84 V, 0-3 A (not a lot, but enough for electronics), limited to 100 W   * wide voltage range (0-50 V): 0-84 V, 0-3 A (not a lot, but enough for electronics), limited to 100 W
-  * silent: not fan, full passive cooling+  * silent: no fan, full passive cooling
   * have an earth connection: on the front panel   * have an earth connection: on the front panel
   * not expensive: ~ 80 €   * not expensive: ~ 80 €
   * not noname: Elektro-Automatik (never heard of it, but it's German and they have a decent website)   * not noname: Elektro-Automatik (never heard of it, but it's German and they have a decent website)
   * provide a communication interface: USB with proprietary documented protocol   * provide a communication interface: USB with proprietary documented protocol
 +
 +{{:ea-ps_2084-03b:dsc02164-mini.jpg?400|}}
  
 Here some more documents about this power supply: Here some more documents about this power supply:
Line 33: Line 35:
   * [[http://www.elektroautomatik.de/files/eautomatik/treiber/ps2000b/programming_ps2000b.zip|programming manual]] ({{:ea-ps_2084-03b:programming_ps2000b.zip|archive}})   * [[http://www.elektroautomatik.de/files/eautomatik/treiber/ps2000b/programming_ps2000b.zip|programming manual]] ({{:ea-ps_2084-03b:programming_ps2000b.zip|archive}})
   * [[http://www.elektroautomatik.de/files/eautomatik/treiber/usb/usb_cdc_acm_driver.zip|driver]] (USB ACM for Windows)   * [[http://www.elektroautomatik.de/files/eautomatik/treiber/usb/usb_cdc_acm_driver.zip|driver]] (USB ACM for Windows)
-  * [[http://www.elektroautomatik.de/en/easyps2000-en.html|easyPS2000 software]] (Windows, demo version)+  * [[http://www.elektroautomatik.de/en/easyps2000.html|easyPS2000 software]] (Windows, demo version)
  
 ====== measurement ====== ====== measurement ======
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 But doing that manually just takes to long. But doing that manually just takes to long.
 So I decided to implement the protocol to control the the power supply, and I will measure the set output using a DMM connected to the computer. So I decided to implement the protocol to control the the power supply, and I will measure the set output using a DMM connected to the computer.
 +
 +{{:ea-ps_2084-03b:dsc02146-mini.jpg?400|}}
  
 ===== power supply ===== ===== power supply =====
  
 To control the power supply I implemented the protocol described in the {{:ea-ps_2084-03b:ps2000b_programming.pdf|programming manual}}. To control the power supply I implemented the protocol described in the {{:ea-ps_2084-03b:ps2000b_programming.pdf|programming manual}}.
-The source code is available on [[https://git.cuvoodoo.info/kingkevin/ea-ps_2084-03b/tree/master|git]].+The source code is available on [[https://git.cuvoodoo.info/kingkevin/ea-ps_2084-03b/|git]].
  
-The [[https://git.cuvoodoo.info/kingkevin/ea-ps_2084-03b/blob/master/control.rb|control]] programming will increment the voltage from 0 to 84 V in 0.1 V steps, at 1.0 A. +The [[https://git.cuvoodoo.info/kingkevin/ea-ps_2084-03b/src/branch/master/control.rb|control]] programming will increment the voltage from 0 to 84 V in 0.1 V steps, at 1.0 A. 
-It will set the voltage and current which are set, actual (measured by the power supply), and [[#mutli-meter|measured]] (measured by the DMM)+It will set the voltage and current which are set, actual (measured by the power supply), and [[#mutlimeter|measured]] (measured by the DMM)
  
-===== multi-meter =====+Using [[https://git.cuvoodoo.info/kingkevin/ea-ps_2084-03b/src/branch/master/probe.rb|this script]] I could also find the following undocumented objects (for commands): 80, 81, 82, 83, 84, 85, 86, 87, 88, 149, 150, 151, 152, 156, 158, 160, 161, 162. 
 +These probably allow you to flash the firmware or calibrate the power supply. 
 +===== multimeter =====
  
 To measure the output of the power supply I used two [[http://uni-trend.com/UT61E.html|UNI-T UT61E]]. To measure the output of the power supply I used two [[http://uni-trend.com/UT61E.html|UNI-T UT61E]].
-These are good multimeters for electronics which you can get [[http://www.aliexpress.com/wholesale?catId=0&SearchText=uni-t+ut61e|quite cheap]], with 22000 counts, and offer connection to the PC.+These are good multimeters for electronics which you can get [[http://www.aliexpress.com/wholesale?catId=0&SearchText=uni-t+ut61e|quite cheap]], with 22000 counts, and connection to the PC.
 More functions and its accuracy are available in the [[http://uni-trend.com/manual2/UT61English.pdf|manual]] ({{:ea-ps_2084-03b:ut61english.pdf|archive}}). More functions and its accuracy are available in the [[http://uni-trend.com/manual2/UT61English.pdf|manual]] ({{:ea-ps_2084-03b:ut61english.pdf|archive}}).
  
 ==== connection ==== ==== connection ====
 +
 +=== UT-D02 ===
  
 The DMM comes with an RS232 [[http://www.uni-trend.com/en/product/2014_0626_553.html|UT-D02]] cable. The DMM comes with an RS232 [[http://www.uni-trend.com/en/product/2014_0626_553.html|UT-D02]] cable.
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 Finally I found a FT232-based RS232 to USB converter. Finally I found a FT232-based RS232 to USB converter.
 This is an expensive cable (but good quality), from an evil company, and it worked. This is an expensive cable (but good quality), from an evil company, and it worked.
 +
 +Here is the schematic of this cable:
 +
 +{{:ea-ps_2084-03b:ut-d02.svg?400|}}
  
 But instead of using it, I decided to connect the cable to a CP2102-based UART to USB converter. But instead of using it, I decided to connect the cable to a CP2102-based UART to USB converter.
Line 78: Line 90:
   * RS232 signals are inverted compared to UART. This was solved by inverting the signal using an NPN transistor and two resistors.   * RS232 signals are inverted compared to UART. This was solved by inverting the signal using an NPN transistor and two resistors.
  
-More details about the cable and modification is described in this picture:+^ UT-D02 wire ^ CP2102 UART signal ^ PNP ^ 
 +| green | GND | | 
 +| yellow | GND | | 
 +| orange | 5V | | 
 +| | GND | E | 
 +| | 5V + 10kΩ | C | 
 +| brown + 10kΩ | | B | 
 +| | RX | C | 
 + 
 +{{:ea-ps_2084-03b:dsc02143-mini.jpg?400|}} 
 + 
 +=== UT-D04 === 
 + 
 +For the second multimeter I used a [[http://www.uni-trend.com/en/product/2014_0626_555.html|UT-D04]] USB cable
 +This time the data doesn't come over a serial port, but rather a HID device. 
 + 
 +==== communication ==== 
 + 
 +To read the data from both multimeter I used [[http://sigrok.org/|sirgork]]. 
 +It supports the [[http://sigrok.org/wiki/UNI-T_UT61E|UNI-T UT61E]] and [[http://sigrok.org/wiki/Device_cables#UNI-T_UT-D02|both]] [[http://sigrok.org/wiki/Device_cables#UNI-T_UT-D04|cables]]. 
 + 
 +Once [[http://sigrok.org/wiki/Sigrok-cli|sigrok-cli]] installed you can record the data using the following command: 
 +<code> 
 +sigrok-cli --driver uni-t-ut61e-ser:conn=/dev/ttyUSB0 --samples 1 -O analog 
 +</code> 
 +or 
 +<code> 
 +sigrok-cli --driver uni-t-ut61e:conn=1a86.e008 --samples 1 -O analog 
 +</code> 
 +depending on the cable. 
 + 
 +====== experiments and results ====== 
 + 
 +I've run 5 experiments: 
 +  * go from 0 V to 84 V in 0.1 V increments, without any load 
 +  * go from 0 V to 84 V at 1.0 A in 0.1 V increments, with a 678 Ω load 
 +  * go from 0 V to 11 V at 1.0 A in 0.1 V increments, with a 10.2 Ω load 
 +  * go from 0 A to 3 A in 0.1 A increments, with a short 
 +  * go from 0 A to 1 A at 10 V in 0.01 A increments, with a 10.2 Ω load 
 + 
 +After changing a value I've waited 3 seconds for the measurements to stabilized. 
 + 
 +The measurements and accuracy calculations are available in this {{:ea-ps_2084-03b:accuracy.tar.gz|spreadsheet}}. 
 + 
 +Here are the resulting graphs: 
 +  * go from 0 V to 84 V in 0.1 V increments, without any load 
 +{{:ea-ps_2084-03b:voltage-no_load-difference.svg?900}} 
 +{{:ea-ps_2084-03b:voltage-no_load-set_accuracy.svg?900}} 
 +{{:ea-ps_2084-03b:voltage-no_load-nominal_accuracy.svg?900}} 
 +  * go from 0 V to 84 V at 1.0 A in 0.1 V increments, with a 678 Ω load 
 +{{:ea-ps_2084-03b:voltage-678_ohms-difference.svg?900}} 
 +{{:ea-ps_2084-03b:voltage-678_ohms-set_accuracy.svg?900}} 
 +{{:ea-ps_2084-03b:voltage-678_ohms-nominal_accuracy.svg?900}} 
 +  * go from 0 V to 11 V at 1.0 A in 0.1 V increments, with a 10.2 Ω load 
 +{{:ea-ps_2084-03b:voltage-10_ohms-difference.svg?900}} 
 +{{:ea-ps_2084-03b:voltage-10_ohms-set_accuracy.svg?900}} 
 +{{:ea-ps_2084-03b:voltage-10_ohms-nominal_accuracy.svg?900}} 
 +  * go from 0 A to 3 A in 0.1 A increments, with a short 
 +{{:ea-ps_2084-03b:current-short-difference.svg?900}} 
 +{{:ea-ps_2084-03b:current-short-set_accuracy.svg?900}} 
 +{{:ea-ps_2084-03b:current-short-nominal_accuracy.svg?900}} 
 +  * go from 0 A to 1 A at 10 V in 0.01 A increments, with a 10.2 Ω load 
 +{{:ea-ps_2084-03b:current-10_ohms-difference.svg?900}} 
 +{{:ea-ps_2084-03b:current-10_ohms-set_accuracy.svg?900}} 
 +{{:ea-ps_2084-03b:current-10_ohms-nominal_accuracy.svg?900}} 
 + 
 +As you can see the measured values are most of the time higher than the set values, but within the 0.2 % accuracy (to 84V or 3A). 
 +But the actual values displayed by the power supply is way below what is set, and outside of the accuracy, particularly on the low voltages. 
 + 
 +Conclusion: don't trust the displayed voltage (it's too low), but you can be confident the output is right (except for the very low voltages and currents). 
 + 
 +====== teardown ====== 
 + 
 +Well laid out, good components, german quality ;) 
 + 
 +{{:ea-ps_2084-03b:dsc02155-mini.jpg?175|}} 
 +{{:ea-ps_2084-03b:dsc02154-mini.jpg?300|}} 
 +{{:ea-ps_2084-03b:dsc02151-mini.jpg?175|}} 
 + 
 +{{:ea-ps_2084-03b:dsc02157-mini.jpg?200|}} 
 +{{:ea-ps_2084-03b:dsc02159-mini.jpg?200|}} 
 +{{:ea-ps_2084-03b:dsc02148-mini.jpg?200|}} 
 +{{:ea-ps_2084-03b:dsc02150-mini.jpg?120|}} 
 + 
 +{{:ea-ps_2084-03b:dsc02156-mini.jpg?200|}} 
 +{{:ea-ps_2084-03b:dsc02160-mini.jpg?200|}} 
 +{{:ea-ps_2084-03b:dsc02163-mini.jpg?200|}} 
 +{{:ea-ps_2084-03b:dsc02162-mini.jpg?200|}} 
 + 
 +====== conclusion ====== 
 + 
 +pro: 
 +  * fulfils all initial power supply criteria  
 +  * **set output is within accuracy** 
 +  * good design, lay out, quality components 
 +  * fast first contact response 
 + 
 +contra: 
 +  * output is not switched of completely 
 +  * **measured value is up to 0.4 V lower than output voltage** 
 +  * second digit after . of voltage is always 0 and not settable (it should not be displayed in this case) 
 +  * second digit after . of voltage is always 0 and does not show measured value (the actual measured data is precise enough to show this digit) 
 +  * can skip fast knob turns 
 +  * USB cable does no fit in port because of the indent 
 +  * information in english programming manual missing 
 +  * small mistakes in programming manual 
 +  * can not be calibrated by end user, and vendor only calibrates if under warranty 
 +  * no contact support
ea-ps_2084-03b.1432752333.txt.gz · Last modified: 2024/01/07 17:49 (external edit)

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