HTTP JSON Sensor Data: Unterschied zwischen den Versionen
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=Preface= | =Preface= | ||
− | * | + | This document tries to explain how to get sensor data by HTTP/Json for programmers. |
− | * | + | |
+ | *All sensor data is available in a generic [https://json.org JSON] Object, presented by status.json | ||
+ | *There are two relevant sub-objects: '''sensor_values''' and '''sensor_descr''' | ||
*sensor_descr can tell | *sensor_descr can tell | ||
− | ** | + | **What sensor types are actually relevant |
− | ** | + | **What is the field description of each of those sensor types |
− | ** | + | **How many sensors of each type are actually present |
− | ** | + | **What are the names of each of those sensors |
*sensor_values carries all measured sensor values, matching the description explained above, in the same order | *sensor_values carries all measured sensor values, matching the description explained above, in the same order | ||
− | * | + | *It's common practice to get sensor_descr+sensor_values once, and '''poll sensor_values only''' subsequently with much less payload |
+ | **(while it's perfectly legit to always get sensor_values alone and rely on sensor type specific knowledge coded within your application's source) | ||
This empowers you to '''write small code supporting all products and all sensors in one single future-proof approach''', without the need for sensor specific knowledge. | This empowers you to '''write small code supporting all products and all sensors in one single future-proof approach''', without the need for sensor specific knowledge. | ||
− | So your software is already prepared for new | + | So your software is already prepared for new Gude-devices, and prepared for new sensor Add-Ons. |
To give an example, this documentation will highly depend on [https://github.com/gudesystems/check_gude.py check_gude.py], our HTTP sensor data swiss-knife tool. | To give an example, this documentation will highly depend on [https://github.com/gudesystems/check_gude.py check_gude.py], our HTTP sensor data swiss-knife tool. | ||
Zeile 20: | Zeile 23: | ||
*HTTP-Get '''status.json?components=8470528''' | *HTTP-Get '''status.json?components=8470528''' | ||
**for more info about status.json components flags, refer to [[EPC HTTP Interface]] | **for more info about status.json components flags, refer to [[EPC HTTP Interface]] | ||
− | **8470528 sums up sensor_values (16384 aka | + | **8470528 sums up '''sensor_values''' (16384 aka 0x4000) plus '''sensor_descr''' (65536 aka 0x10000), plus the ‘'''extended'''’ marker (8388608 aka 0x800000) to get both simple sensors and (more complex) sensor groups |
**8470528 = 0x814000 = 0x4000 + 0x10000 + 0x800000 | **8470528 = 0x814000 = 0x4000 + 0x10000 + 0x800000 | ||
− | = Example data = | + | = Example JSON data = |
== sensor_descr == | == sensor_descr == | ||
[ | [ | ||
Zeile 34: | Zeile 37: | ||
], | ], | ||
"properties": [ | "properties": [ | ||
− | { "id": "L1", "name": "Meter1" | + | { "id": "L1", "name": "Meter1"}, |
− | { "id": "L2", "name": "Meter2" | + | { "id": "L2", "name": "Meter2"} |
] | ] | ||
}, | }, | ||
Zeile 46: | Zeile 49: | ||
], | ], | ||
"properties": [ | "properties": [ | ||
− | { "id": "6102", "name": "Server-Rack" | + | { "id": "6102", "name": "Server-Rack"} |
] | ] | ||
} | } | ||
Zeile 53: | Zeile 56: | ||
This tells you: | This tells you: | ||
* There a two sensors of type 664, and one of type 665 | * There a two sensors of type 664, and one of type 665 | ||
− | * A type-664 sensor has two Fields, Voltage and | + | * A type-664 sensor has two Fields, Voltage 'V' and Current 'A' |
** Voltage is measured with a decimal precision of 3, Ampere with a decimal precision of 1 | ** Voltage is measured with a decimal precision of 3, Ampere with a decimal precision of 1 | ||
* The two type-664 sensors (L1 and L2) are named 'Meter1' and 'Meter2' | * The two type-664 sensors (L1 and L2) are named 'Meter1' and 'Meter2' | ||
Zeile 77: | Zeile 80: | ||
] | ] | ||
− | == | + | == sensor_descr / sensor_values == |
− | + | Bringing together both objects will assemble the complete sensor information: | |
− | '''L1/Meter1''' 233.19 V (Voltage), 3.2 A (Ampere) | + | '''L1/Meter1''' 233.19 V (Voltage), 3.2 A (Ampere) |
− | '''L2/Meter2''' 226.20 V (Voltage), 0.3 A (Ampere) | + | '''L2/Meter2''' 226.20 V (Voltage), 0.3 A (Ampere) |
− | + | '''6102/Server-Rack:''' 27.1 C (Temperature), 40.3 % (Humidity) | |
− | '''6102/Server-Rack:''' 27.1 C (Temperature), 40.3 % (Humidity) | ||
= Common sensor type IDs = | = Common sensor type IDs = | ||
1 Line power meter | 1 Line power meter | ||
− | 9 Line power meter with residual | + | 9 Line power meter with residual current |
8 Outlet power meter | 8 Outlet power meter | ||
7 Digital Inputs | 7 Digital Inputs | ||
+ | |||
+ | 12 Bender RCMB Module | ||
20 System Data (sensor group) | 20 System Data (sensor group) | ||
Zeile 108: | Zeile 112: | ||
==Show all Sensor Data== | ==Show all Sensor Data== | ||
*Here a device with hostname [http://8041.demo.gude.info/dashboard.html 8041.demo.gude.info] is queried to dump all sensor data | *Here a device with hostname [http://8041.demo.gude.info/dashboard.html 8041.demo.gude.info] is queried to dump all sensor data | ||
− | * | + | *[https://github.com/gudesystems/check_gude.py check_gude.py]'s command line parameters ''--ssl'' / ''--username'' / ''--password'' will optionally use HTTP encryption and user authentification |
[[Bild:Check gude py 1.png]] | [[Bild:Check gude py 1.png]] | ||
==show CGI-Get / JSON Data == | ==show CGI-Get / JSON Data == | ||
− | when using --verbose [https://github.com/gudesystems/check_gude.py check_gude.py] will print out the full URL and the JSON return data: | + | when using --verbose, [https://github.com/gudesystems/check_gude.py check_gude.py] will print out the full URL and the JSON return data: |
[[Bild:Check gude py 2.png]] | [[Bild:Check gude py 2.png]] | ||
= Sensor groups = | = Sensor groups = | ||
− | A simple sensor has one single field description, as shown above, where a sensor group is a bundle of different field descriptions | + | A simple sensor has one single field description, as shown above, where a sensor group is a bundle of different field descriptions. |
+ | |||
So instead of presenting 'fields', it has 'groups' as list of 'fields' | So instead of presenting 'fields', it has 'groups' as list of 'fields' | ||
==Sensor group example== | ==Sensor group example== | ||
*This is a virtual sensor 'engine' | *This is a virtual sensor 'engine' | ||
+ | *Each engine has a certain amount of cylinders, and a certain amount of telemetry sensors | ||
*Each vehicle can have multiple engines | *Each vehicle can have multiple engines | ||
− | + | *In this example, our car (device) has two engines, ''Front Engine'' and ''Rear Engine'' | |
− | *In this example, our car has two engines, ''Front Engine'' and ''Rear Engine'' | ||
**Front-engine has 4 cylinders, and 1 telemetry sensor | **Front-engine has 4 cylinders, and 1 telemetry sensor | ||
**Rear-engine has 2 cylinders, and no telemetry sensor | **Rear-engine has 2 cylinders, and no telemetry sensor | ||
Zeile 206: | Zeile 211: | ||
} | } | ||
− | == | + | == check_gude.py with sensor groups == |
− | check_gude would compile both objects like this: | + | [https://github.com/gudesystems/check_gude.py check_gude.py] would compile both objects like this: |
./check_gude.py -H mycar.local.net | ./check_gude.py -H mycar.local.net | ||
Zeile 222: | Zeile 227: | ||
666.0.0.2.1 <font color="blue">0.4</font> W power | 666.0.0.2.1 <font color="blue">0.4</font> W power | ||
'''C4''' Cylinder4 | '''C4''' Cylinder4 | ||
− | 666.0.0. | + | 666.0.0.3.0 <font color="blue">4.5</font> milli-brown flux |
− | 666.0.0. | + | 666.0.0.3.1 <font color="blue">1.5</font> W power |
'''T1''' Temperature1 | '''T1''' Temperature1 | ||
666.0.1.0.0 <font color="blue">83.9</font> C Temperature | 666.0.1.0.0 <font color="blue">83.9</font> C Temperature | ||
Zeile 234: | Zeile 239: | ||
666.1.0.1.0 <font color="blue">13.4</font> milli-brown flux | 666.1.0.1.0 <font color="blue">13.4</font> milli-brown flux | ||
666.1.0.1.1 <font color="blue">4.3</font> W power | 666.1.0.1.1 <font color="blue">4.3</font> W power | ||
+ | |||
+ | ==Expert Power Control 8291== | ||
+ | *Using the ''sensor group'' principles described above, the '''Expert Power Control 8291''' defines outlet groups as 'bank'/'efuse' sensor | ||
+ | *Each bank can have multiple outlets, along with multiple power sensors | ||
+ | *Each device can have multiple banks sensors | ||
+ | *In this example | ||
+ | **The device has two banks, A and B | ||
+ | **Bank A has two outlets (A1, A2) with one power sensors S1. | ||
+ | **Bank B has one outlet (B1) with one power sensors S2 | ||
+ | |||
+ | |||
+ | ./check_gude.py -H 8291.demo.gude.info | ||
+ | |||
+ | [...] | ||
+ | Bank A | ||
+ | 1 A1 | ||
+ | 101.0.0.0.0 0 Enabled // 0 = off, 1 = on | ||
+ | 101.0.0.0.1 0 Power // 0 = 'no Power', 1 = 'Power' | ||
+ | 101.0.0.0.2 0 State // 0 = 'normal off', 1 = 'normal on', 2=efuse error1, 3=efuse error2 | ||
+ | 2 A2 | ||
+ | 101.0.0.1.0 0 Enabled | ||
+ | 101.0.0.1.1 0 Power | ||
+ | 101.0.0.1.2 0 State | ||
+ | S1 5V | ||
+ | 101.0.1.0.0 DC | ||
+ | 101.0.1.0.1 4.988 V Voltage | ||
+ | 101.0.1.0.2 0 A Current | ||
+ | Bank B | ||
+ | 3 B1 | ||
+ | 101.1.0.0.0 0 Enabled | ||
+ | 101.1.0.0.1 0 Power | ||
+ | 101.1.0.0.2 0 State | ||
+ | S2 DC 12V | ||
+ | 101.1.1.0.0 DC | ||
+ | 101.1.1.0.1 12.036 V Voltage | ||
+ | 101.1.1.0.2 0 A Current | ||
+ | |||
+ | [...] |
Aktuelle Version vom 16. November 2022, 08:36 Uhr
Preface
This document tries to explain how to get sensor data by HTTP/Json for programmers.
- All sensor data is available in a generic JSON Object, presented by status.json
- There are two relevant sub-objects: sensor_values and sensor_descr
- sensor_descr can tell
- What sensor types are actually relevant
- What is the field description of each of those sensor types
- How many sensors of each type are actually present
- What are the names of each of those sensors
- sensor_values carries all measured sensor values, matching the description explained above, in the same order
- It's common practice to get sensor_descr+sensor_values once, and poll sensor_values only subsequently with much less payload
- (while it's perfectly legit to always get sensor_values alone and rely on sensor type specific knowledge coded within your application's source)
This empowers you to write small code supporting all products and all sensors in one single future-proof approach, without the need for sensor specific knowledge.
So your software is already prepared for new Gude-devices, and prepared for new sensor Add-Ons.
To give an example, this documentation will highly depend on check_gude.py, our HTTP sensor data swiss-knife tool.
Getting data by HTTP
- HTTP-Get status.json?components=8470528
- for more info about status.json components flags, refer to EPC HTTP Interface
- 8470528 sums up sensor_values (16384 aka 0x4000) plus sensor_descr (65536 aka 0x10000), plus the ‘extended’ marker (8388608 aka 0x800000) to get both simple sensors and (more complex) sensor groups
- 8470528 = 0x814000 = 0x4000 + 0x10000 + 0x800000
Example JSON data
sensor_descr
[ { "type": 664, "num": 2, "fields": [ {"name": "Voltage", "unit": "V", "decPrecision": 3}, {"name": "Current", "unit": "A", "decPrecision": 1} ], "properties": [ { "id": "L1", "name": "Meter1"}, { "id": "L2", "name": "Meter2"} ] }, { "type": 665, "num": 1, "fields": [ {"name": "Temperature", "unit": "C", "decPrecision": 1}, {"name": "Humidity", "unit": "%", "decPrecision": 1} ], "properties": [ { "id": "6102", "name": "Server-Rack"} ] } ]
This tells you:
- There a two sensors of type 664, and one of type 665
- A type-664 sensor has two Fields, Voltage 'V' and Current 'A'
- Voltage is measured with a decimal precision of 3, Ampere with a decimal precision of 1
- The two type-664 sensors (L1 and L2) are named 'Meter1' and 'Meter2'
- The one type-665 sensor is named 'Sever-Rack', and has two fields 'Temperature' and 'Humidity'
sensor_values
[ { "type": 664, "num": 2, "values": [ [{"v": 233.19}, {"v": 3.2}], [{"v": 226.2}, {"v": 0.3}] ] }, { "type": 665, "num": 1, "values": [ [{"v": 27.1}, {"v": 40.3}] ] } ]
sensor_descr / sensor_values
Bringing together both objects will assemble the complete sensor information:
L1/Meter1 233.19 V (Voltage), 3.2 A (Ampere) L2/Meter2 226.20 V (Voltage), 0.3 A (Ampere) 6102/Server-Rack: 27.1 C (Temperature), 40.3 % (Humidity)
Common sensor type IDs
1 Line power meter 9 Line power meter with residual current 8 Outlet power meter 7 Digital Inputs 12 Bender RCMB Module 20 System Data (sensor group) 51 Temperature Sensor 52 Temperature/Humidity Sensor 53 Temperature/Humidity/AirPressure Sensor 101 Bank (eFuses Port-groups) Sensor (e.g. used at 8291 PDUs) 102 (DC) Power Sources (e.g. used at 8291 PDUs)
check_gude.py in action
- check_gude.py is a demo code to show how sensor_descr and sensor_values can be assembled generically to make use of all our devices / sensors
- so when new devices and sensors are coming up, check_gude.py is already prepared to deal with it
- install python along with the python module requests, to run check_gude.py
- feel free to use check_gude.py as you need it and to rewrite the given code to any language desired
Show all Sensor Data
- Here a device with hostname 8041.demo.gude.info is queried to dump all sensor data
- check_gude.py's command line parameters --ssl / --username / --password will optionally use HTTP encryption and user authentification
show CGI-Get / JSON Data
when using --verbose, check_gude.py will print out the full URL and the JSON return data:
Sensor groups
A simple sensor has one single field description, as shown above, where a sensor group is a bundle of different field descriptions.
So instead of presenting 'fields', it has 'groups' as list of 'fields'
Sensor group example
- This is a virtual sensor 'engine'
- Each engine has a certain amount of cylinders, and a certain amount of telemetry sensors
- Each vehicle can have multiple engines
- In this example, our car (device) has two engines, Front Engine and Rear Engine
- Front-engine has 4 cylinders, and 1 telemetry sensor
- Rear-engine has 2 cylinders, and no telemetry sensor
sensor_descr
{ "type": 666, "num": 2, "groups": [ { "name": "cylinder", "fields" : [ {"name": "flux", "unit": "milli-brown", "decPrecision": 0}, {"name": "Power", "unit": "W", "decPrecision": 1} ] }, { "name": "telemetry", "fields" : [ {"name": "Temperature", "unit": "C", "decPrecision": 1} ] } ], "properties": [ { "id": "E1", "name": "Front Engine", "groups": [ [ {"id": "C1", "name": "Cylinder1"}, {"id": "C2", "name": "Cylinder2"}, {"id": "C3", "name": "Cylinder3"}, {"id": "C4", "name": "Cylinder4"} ], [ {"id": "T1", "name": "Temperature1"} ] ] }, { "id": "E2", "name": "Rear Engine", "groups": [ [ {"id": "C1", "name": "Cylinder1"}, {"id": "C2", "name": "Cylinder2"} ], [ ] ] } ] }
sensor_values
{ "type": 666, "num": 2, "values": [ [ [ [{"v": 12.3}, {"v": 12.3}], [{"v": 35.1}, {"v": 0.3}], [{"v": 25.6}, {"v": 0.4}], [{"v": 4.5}, {"v": 1.5}] ], [ [{"v": 83.9}] ] ], [ [ [{"v": 12.3}, {"v": 12.3}], [{"v": 35.1}, {"v": 0.3}], ], [ ] ] ] }
check_gude.py with sensor groups
check_gude.py would compile both objects like this:
./check_gude.py -H mycar.local.net
E1 Engine 1 C1 Cylinder1 666.0.0.0.0 12.3 milli-brown flux 666.0.0.0.1 2.5 W power C2 Cylinder2 666.0.0.1.0 35.1 milli-brown flux 666.0.0.1.1 0.3 W power C3 Cylinder3 666.0.0.2.0 25.6 milli-brown flux 666.0.0.2.1 0.4 W power C4 Cylinder4 666.0.0.3.0 4.5 milli-brown flux 666.0.0.3.1 1.5 W power T1 Temperature1 666.0.1.0.0 83.9 C Temperature E2 Engine 2 C1 Cylinder1 666.1.0.0.0 46.1 milli-brown flux 666.1.0.0.1 8.6 W power C2 Cylinder2 666.1.0.1.0 13.4 milli-brown flux 666.1.0.1.1 4.3 W power
Expert Power Control 8291
- Using the sensor group principles described above, the Expert Power Control 8291 defines outlet groups as 'bank'/'efuse' sensor
- Each bank can have multiple outlets, along with multiple power sensors
- Each device can have multiple banks sensors
- In this example
- The device has two banks, A and B
- Bank A has two outlets (A1, A2) with one power sensors S1.
- Bank B has one outlet (B1) with one power sensors S2
./check_gude.py -H 8291.demo.gude.info [...] Bank A 1 A1 101.0.0.0.0 0 Enabled // 0 = off, 1 = on 101.0.0.0.1 0 Power // 0 = 'no Power', 1 = 'Power' 101.0.0.0.2 0 State // 0 = 'normal off', 1 = 'normal on', 2=efuse error1, 3=efuse error2 2 A2 101.0.0.1.0 0 Enabled 101.0.0.1.1 0 Power 101.0.0.1.2 0 State S1 5V 101.0.1.0.0 DC 101.0.1.0.1 4.988 V Voltage 101.0.1.0.2 0 A Current Bank B 3 B1 101.1.0.0.0 0 Enabled 101.1.0.0.1 0 Power 101.1.0.0.2 0 State S2 DC 12V 101.1.1.0.0 DC 101.1.1.0.1 12.036 V Voltage 101.1.1.0.2 0 A Current [...]