EmonTx V3

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THIS DOCUMENTATION PAGE IS A WORK IN PROGRESS - please bear with us while we flesh out this page in the coming days. Please help where you can to fix typos and add missing info. Your login user from openenergymonitor.org should carry over to the wiki. You might need to logout then log back into openenergymonitor.org before loading the wiki to be able to edit it.

emonTx V3

The emontx V3 is the latest generation of the emonTx Low Power Wireless Energy Monitoring Node designed for monitoring AC electrical power on (up to) 4 separate (household/building) circuits using non-invasive clip on CT current sensors and an AC-AC Voltage adaptor to provide a voltage signal for full Real Power calculations.

emonTx V3 Setup emonTx V3 PCB emonTx V 3 PCB assembled


  • emonTx v3 can measure apparent power, real power*, power factor*, RMS voltage* and current on 4 different mains circuits, it also has inputs for temperature and humidity sensing.
  • Pre-assembled SMT design
  • A single AC-AC adapter can now be used to power the emonTx V3 and provide AC voltage measurement
  • 4x CT current sensing inputs
  • An on-board 3x AA battery option
  • Flexible choice of RF radio module and removable microcontroller
  • when AC-AC voltage adapter is connected

Port Map

emonTx V3 Ports emonTx V3 Port map


Using an ATmega328 microprocessor the emonTx V3 runs standard Arduino sketches and is easy to customise and upload code using the Arduino IDE and a USB to UART cable.

The data from the emonTx V3 is transmitted via wireless (433/868Mhz) to an emonBase web-connected base-station (we recommend a Raspberry Pi with an RFM12Pi) which then posts the data onto an emoncms server (e.g. emoncms.org) for logging, processing and graphing.

The main board of the emonTx V3 comes pre-assembled, just requiring the addition of the RFu328 and optionally a battery holder added to get going. However if the 'fully-built' option has been selected in the emonTx V3 Bundle Builder then the emonTx V3 will come with the Rfu328 already fitted (using Xbee style 2mm headers) and with firmware ready uploaded. If this is the case skip to step 3 below.

Power Supply Options

There are four ways to power the emonTx V3:

  1. USB to UART cable - only recommended for short periods while programming, it is recommended to remove all other power sources
  2. 5V DC Mini-USB cable - remove jumper JP2 when powering via DC if AC adapter is present
  3. 3 x AA Batteries - remove jumper JP2 when powering via DC if AC adapter is present
  4. 9V AC-AC power adapter - with jumper JP2 closed (If jumper 2 is left open then the AC-AC adapter will be used for power sampling but not to power the emonTx V3 - see Powering via AC below)

Powering via DC (1-3)

When powering the emonTx V3 via DC (1-3) (and running the main emonTx firmware (emonTxV3_RFM12B_DiscreteSampling)) the emonTx V3 will take Apparent Power measurements, measuring only current, assuming the Power Factor of 1 and Vrms to be 230V, power saving mode will also be implemented, going into sleep mode in between readings (default every 10s) to save battery power.

The red LED indicator will illuminate for a couple of seconds then extinguish never to flash again if powering from a DC source. If the LED flashes multiple times at startup this indicates the emonTx is detecting an AC waveform - this can happen if an AC adapter has just been removed, hit the reset button if this occurs. When powering the unit via 5V USB/battery it is advisable to remove the JP2 jumper if an AC-AC adapter is present.

Powering via AC (4)

A nice feature of the emonTx V3 is the ability to use an AC-AC adapter to power the unit at the same time as simultaneously providing an AC voltage waveform sample. If the emonTx V3 detects the presence of an AC waveform (AC adapter connected) at startup it will automatically implement Real Power and Irms measurements by sampling the AC waveform. Real Power is what you get billed for and can sometimes (depending on the appliances connected to the circuit being monitored) vary significantly from Apparent Power - see Building Blocks for more info on AC power theory. For best power monitoring accuracy we recommend powering with an AC-AC adapter whenever possible.

Using the AC voltage waveform for reference also enables the emonTx to monitor the direction of the current flow, this is important for solar PV monitoring, if you notice a negative reading when you were expecting a positive one, flip the orientation of the CT. The red indicator LED will flash at startup then flash once every 10's to indicate that an AC waveform has been detected. Sleep mode will be disabled to keep a more consistent power draw on the AC circuit.

Important note regarding powering with AC: powering via AC is only recommended for standard emonTx operation without auxiliary sensors (apart from a single DS128B20 temperature sensor) or equipment (e.g. relay modules) connected. If the current draw exceeds 20mA the AC voltage waveform sample will be effected, adversely effecting the reading accuracy of the emonTx. To avoid damage to the emonTx V3's circuits the current drawn from the AC circuit should never exceed 60mA - see technical wiki for more info. If more than 20mA of current is required it is recommended to remove jumper 2 (JP2) and power the emonTx via 5V USB. If an AC-AC adapter is connected it will only be used to provide an AC sample when JP2 is removed.

Uploading Arduino Firmware

Compiling and Uploading using Arduino IDE

The emonTx V3 with the RFu328 uses the ATmega328 microcontroller (same as Arduino Uno) and comes with the Optiboot (Arduino Uno) serial bootloader installed. This makes it super easy to upload new code to the emonTx V3 from the Arduino IDE.

A USB to UART cable is required to upload new Arduino firmware sketches

Start by downloading the firmware, libraries and setting up the Arduino programming environment by following this guide:

Setting up the Arduino Programming Enviroment

Once complete the emonTx V3 firmware location should be navigable from within the Arduino IDE by going to:

File > Sketchbook > OpenEnergyMonitor > emonTxFirmware > emonTxV3

Flashing Pre-compiled .hex

The main emonTx V3 emonTxV3_RFM12B_Discrete Sampling firmware as pre-loaded onto pre-build emonTx is also supplied as a pre-compiled .hex file.

GitHub can be used to make sure you have the latest version:

$ git clone https://github.com/openenergymonitor/emonTxFirmware.git $ cd emonTxFirmware/emonTxV3/RFM12B/emonTxV3_RFM12B_DiscreteSampling

Linux : use AVRdude

$ sudo apt-get install avrdude

$ avrdude -v -c arduino -p ATMEGA328P -P /dev/ttyUSB0 -b 115200 -U flash:w:emonTxV3_RFM12B_DiscreteSampling.cpp433.hex

Specifying the USB port of your USB to UART programmer and the correct name and location of the .hex file

Windows :you might be able to use the the XLoader application to upload .hex files (we have not tested this ourselves, please update wiki if you have)

Arduino Firmware Info

See GitHub readme for firmware info:

All emonTx V3 firmware is available on Github:emonTxFirmware

All emonTx V3's sold pre-assembled are shipped with emonTxV3_RFM12B_Discrete Sampling firmware. This is the main firmware for the emonTx V3 and has been tested and calibrated. This firmware has the following features:

  • Detection of AC-AC adapter sets Apparent Power / Real Power Sampling accordingly
  • Detection of battery / USB 5V or AC > DC power method and sets sleep mode accordingly
  • Detection of CT connections and samples only from the channels needed
  • Detection of remote DS18B20 temperature sensor connection

The emonTxV3_RFM12B_Discrete Sampling firmware samples over 10 full AC cycles, so 200ms per measurement on each CT. Within this measurement it samples rapidly at about 2500 samples per second. There is then an assumption that the power does not fluctuate significantly in the time it is asleep, which is usually good enough for typical household monitoring. If greater precision is required (as is the case with PV Power Diversion it is recommended that you use PLL continuous sampling, see RFM12B firmware examples folder on GitHub.

Standard Operation

CT Energy Monitoring

Single Phase



Extended Operation

Temperature Monitoring

A DS18B20 digital temperature sensor can easily be connected by the emonTx V3 by connecting the sensor into the emonTx V3's screw terminal block. The default firmware supports auto-detecting one DS18B20 sensor. Many DS18B20's can be daisy-chained but this will require changes being made to the pre-installed emonTx firmware - you may also run into power draw issues depending on how you are powering the emonTx (see Power Supply Options above).

In order to save power when running off batteries the emonTx V3 supports switching off of the DS18B20 in-between readings and performing the temperature conversion while the ATmega328 is sleeping. To do this power (3.3V) is supplied to the DS18B20's power pin from Dig5, this digital pin is switched off between readings. The data connection from the DS18B20 is connected to Dig19, this I/O pin has got a 4K7 pull-up resistor on-board the emonTx V3's PCB as required by the DS18B20.

To connect an external DS18B20 to the emonTx V3 screw terminal block connections are as follows

DS18B20 emonTx V3 screw terminal connections
Screw terminal pin DS18B20 Connection
3 - GND GND (Black)
5 - Dig5 Power (Red)
6 - Dig19 Data (White)

Utility Meter Interface

Optical Pulse Counting

Many meters have pulse outputs, including electricity meters (single phase, 3-phase, import and export), gas meters, water flow meters etc. The pulse output may be a flashing LED or a switching relay (usually solid state) or both. We recommend using the optical interface where available as this decouples the monitoring equipment from any high/mains voltages.

In the case of an electricity meter, a pulse output corresponds to a certain amount of energy passing through the meter (KWhr/Wh). For single-phase domestic electricity meters (eg. Elster A100c) each pulse usually corresponds to 1 Wh (1000 pulses per kwh). For water and gas meters they will usually be marked to show the quantity of water (liters/gallons) or of gas (cubic meters/cubic feet) that each pulse represents.

The emonTx V3 has one interrupt input (IRQ 0, Dig2) which can be used for pulse counting. This is broken out on terminal block port 4

The emonTx V3 pulse counting example sketch calculates the power by the calculating the time elapsed between pulses.

Read more about pulse counting on the OpenEnergyMonitor Buillding Block pagers here

emonTx V3 Hardware Connections

You should connect the pulse input into emonTx V3 terminal block port 4 (IRQ 0 / Digital 2) If you are connecting a hard-wired pulse output you may need to add a pull-down resistor onto the emonTx V3 PCB (R31) If you are using an optical counter (e.g TSL257) you should connecting the power pin to the 3.3V or 5V (if running off 5V USB)

emonTx V3 pulse-counting screw terminal connections
Screw terminal pin Connection
1 5V (if powered via 5V USB)
2 3.3V
4 IRQ 0 / Dig2

We recommend powering the emonTx V3 from either a 5V USB or AC_AC adapter when used for pulse counting operation. Due to the additional power requirements of the optical pulse sensor, battery life will be significantly reduced compared to running an emonTx from 3 x AA batteries for CT operation only.

Direct Optical Interface

if you have an Elster meter (tested with Elster 100C) the emonTx V3 with an IR TSL261R sensor can be used to interface directly with the meter protocol to read off the exact accumulated watt hours that you have generated or used. This reading can be used on it's own or to cross-check and calibrate CT based measurement. See here for original blog post

RF Connectivity


The Rfu328 sold through the OpenEnergyMonitor shop is ready setup for use with the RFM12B, just make sure you solder the RFM12B with the correct orientation if soldering it yourself: the crystal on the RFM12B should be on the same side as the tiny 16Mhz ATmega328 crystal on the RFu328. To use the RFM12B on the RFu328 a modified version of the JeeLib RF12 library has been created. This is called the RFu_JeeLib see GitHub readme for the modifications which have been undertaken. Once using the RFu_JeeLib the RFM12B on the RFu348 can be used exactly the same as before, all code written for the emonTx V2, JeeNode etc should work just fine using using the RFu_JeeLib library.


A Ciseco SRF module can also be used on the emonTx V3 instead of an RFM12B. The easiest thing to do is to purchase a complete RFu328 SRF setup from Ciseco, however, a SRF can be used on the RFu328 purchased from the OpenEnergyMonitor shop with one small modification. The RFu328 sold through the OpenEnergyMonitor shop comes ready setup for use the RFM12B, to use it with the SRF you will need to remove one SMT resistor and rotate another by 90 degress. Follow these instructions from Ciseco IN REVERSE!

Due to the higher power requirements of the SRF it is not possible to power the emonTx V3 from an AC adapter when using an SRF, when an SRF is used the board should be powered via DC and the jumper removed see #Electrical Characteristics - Absolute min / max for power ratings.

SMA Antenna

While an SMA antenna does not improve the gain it does make the antenna setup more durable and allow for the use of an SMA extension cable and remote whip antenna which can be a real lifesaver for installations with tricky RF considerations (thick stone walls, no direct line of sight).

Adding an SMA antenna

Ideally the RFu328 should be soldered directly onto the emonTX via the SMT pads when using an SMA connector (as shown in the photo below) as this directly connects the RF antenna pad on the RFu238 to the PCB antenna track of the emonTx which connects to the SMA connector.


It is possible to use an SMA antenna when the RFu328 has been mounted on headers instead of soldered directly to the SMT pads on the emonTx. To do so you will need to connect the antenna pad of the RFu328 to the antenna pad on the emonTx by using a small wire jumper - the wire jumper and the two pads which need to be connected are shown by the red line on the photo below.

RFu328 Headers showing jumper for SMA

SMA antenna options for emonTx V3
Manufacturer Description Value Package Rapid Code Farnell Code RS Code
Tru Connect SMA PCB connector N/A thru-hole 16-1562 2079861 512-0070
RF-Solutions 434Mhz Ant straight 434Mhz SMA 542-488 1304036 542-535
RF-Solutions 434Mhz Ant 90 degrees 434Mhz SMA 542-488
RF-Solutions 868Mhz Ant straight 868Mhz SMA 1304037 542-551
RF-Solutions 868Mhz Ant 90 degrees 868Mhz SMA 542-563
Ciseco SMA Extension whip antena 5m 433Mhz SMA
Ciseco SMA Extension whip antena 5m 868Mhz SMA

Electrical Characteristics - Absolute min / max

emonTx V3 Datasheet
Function Parameter Min Recommended

Max / typical

Absolute Max

if exceeded damage might happen

CT 1-3 Monitoring Power @ 240V 23kW 60KW Using 22R burden and YHDC SCT-013-00 with 22 turns
CT 4 Monitoring Power @ 240V 4.5kW 4.6kW max measure – 19.7kW max dissipation Using 22R burden and YHDC SCT-013-00 with 22 turns
AC-DC half-wave supply Current output 20mA 60mA Current draw above 20mA AC sample signal will be effected
3.3V Rail current output When powering with 5V USB 150mA 168mA Limitation SOT22 MCP1700 Ta=40C Vi=5.25V
Operating Temperature Temperature -40C +40C +85C
Storage Temperature Not programmed -50C +150C
5V Input Voltage USB/FTDI/5V Aux +3.4V +6V +6.5V (see note 1) See note 1
3.3V Supply Voltage on 3.3V supply rail 2.6V * 3.3V 3.8V RFM12B / 3.6V SRF * *ADC readings will be incorrect if Vcc!=3.3V
Power Consumption RFM12B @3.3V 0.034 mA (MCU sleep + RFM12B sleep) 7.3mA (MCU running) 9-10mA (MCU + LED), 23-28mA for 3ms RFM12B tx With ATmega328, RFM12B and 1 CT connected
Power Consumption SRF @3.3V 0.032 mA (MCU sleep + SRF sleep II) 7.4mA (MCU running, SRF sleep II) 31.24mA (MCU running, SRF awake) With ATmega328, SRF and 1 CT connected

Note 1: A higher voltage (up to 17.6V) can be used to power the emonTx if power is connected into the MCP1754 through the AC-DC enable jumper pin.

Design Calculations

Burden Resistor Calculations

CT 1-3 have got a 22R burden resistor which can measure up to 97A (23.3kW @ 240V) using YHDC SCT-013-00 CT which has 2000 turns.

CT 4 is rated up to 4.6kW using 120R burden

The higher the burden resistor the smaller the range of measurement and the higher the accuracy at the low end of the measurement scale. Burden resistors should be +/- 1%.

Is^=Ip^/turns = Irms x sqrt(2)/turns

Rb= (AREF/2) / Is^ = AREF/ 2Is^

Rb= (AREF * turns) / (2*IpRMS x sqrt(2))

Pmax=(240 * AREF * turns) / (2 *sqrt(2) * Rb)

Rb (100A , 24Kw @ 240V) = 3.3*2000 / 2 x 100 x sqrt(2) = 23.3 Ohm

Closest value = 22R or 24R

We will go for 22R this gives Pmax of 23.3Kw (97.1A) which is close enough to 100A. Measurement 97-100A will be poor anyway since CT starts to saturate.

Pmax=(240 * 3.3 * 2000) / (2 *sqrt(2) * 22) = 23.3Kw

Rb (16.7A , 4Kw @ 240V) = 3.3*2000 / 2 x 16.67 x sqrt(2) = 23.3 O = 139.9 Ohm

Closest value = 120R or 150R

We will go for 120R to rate up to 19.16A or 4.6Kw @ 240V

If the power level does go above the rated power level the voltage will go above 3.3V and the ATmega328’s ADC will be saturated. A 1K series resistor is used to limit the current going into the ATmega. The ATmega 328’s internal voltage clamping diodes will safely clamp the voltage avoiding damage. http://openenergymonitor.org/emon/node/171

CT inserted indication

On the emonTx V3 design the switched jack plug has been utilized to provide a clear indication to show if the CT is connected or not. When a 3.5mm jack plug is NOT inserted pin 3 is connected to pin 2 and pin 4 is connected to pin 5 as shown in the diagram below. Pin 4 has been connected to GND so when no CT is connected ADC will show 0V.

When a 3.5mm jack is inserted the connection is between pin 4 & 5 is broken and the CT channel will works as usual

emonTx V3 Setup

This method will increase quiescent power consumption slightly since 3.3V will be connected to GND through 470K resistor when no CT is connected. This will introduce a current drain of 7uA per channel, so a maximum of total of 21uA on the board (assuming at least 1 CT is always connected). See Quiescent power consumption section.

Burden resistor and capacitor power and voltage ratings

From testing results the maximum current in the secondary at saturation (primary current 250A – 60kW! @ 240V) is 85mA (RMS)

CT 1-3 (up to 23.3kW) use a 22R resistor. The max voltage through the burden at CT saturation will be 1.87V (measured by Robert to be 1.5V RMS). The max power the 22R burden will need to dissipate at CT saturation is 159mW

CT 4 (up to 4.6kW) uses a 120R resistor. Even though this channel is only rated up to 4.6Kw we can’t stop it accidentally being attempted to be used for higher measurement. Components should be rated for saturation. The max voltage through burden at CT saturation will be 10.2V (measured by Robert to be 5.2V rms). The max power the 120R burden will need to dissipate is 867mW

However the emonTx will be specced for domestic use. In the UK the maximum rated fuse/RCB is 100A, most new builds are 80A. Therefore we can safely spec the emonTx for 100A max.

The current in the secondary at 100A is 50mA (RMS).

Max voltage in CT 1-3 22R burden = 1.1Vrms (measured by Robert to be 0.935 Vrms)

Max power in 22R CT = 55mW

Max voltage in CT 4 120R burden = 6V (measured by Robert to be 3.9 V rms)

Max power in 120R burden = 300mA

If a 0.25W resistor was used the maximum current in the secondary would be 42mA this equates to 82A or 19.7Kw. CT4 will be physically removed from CT1-3 and clearly marked as 4.6kW max. Ideally a red colour 3.5mm socket will be used to clearly identify.

Therefore the actual max power will be around 175mW. This give a good margin.

Conclusion: 0.25W burden and 6V capacitor will be suitable ratings. A 0606 X5R 10uF 6.3V filtering capacitor can be used

Given testing results these values have been shown be to conservative, testing results are:

  • 100 A, 22 R: Burden voltage = 0.935 V rms., 2.612 V peak-peak
  • 100 A, 120 R: Burden voltage = 3.89 V rms., 12.07 V peak-peak
  • 250 A, 22 R: Burden voltage = 1.498 V rms., 5.626 V peak-peak
  • 250 A, 120 R: Burden voltage = 5.194 V rms., 21.9 V peak-peak

Max power is thus 225 mW (120 R) or 102 mW (22 R)

These are the maximum rms voltages that can be developed, if 250 mW resistors are used, the actual power is comfortably inside the rating.

Power Supply


The emonTx V3 has been designed to accept power via 5V USB, 3x AA batteries, FTDI connection, Aux input from terminal blocks or from AC power adapter via AC-DC half-wave rectifier circuit.

Only a single source of power should be used at once. DO NOT MIX POWER SOURCES.

In order to keep quiescent power loss to the minimum a SOT32 MCP1700 LDO regulator was chosen for battery, USB 5V and FTDI power (5v) operation. The max input is 6V which is fine for 3 x AA and USB

operation. The regulator has a lower quiescent power consumption than the MCP1702 which is used for the AC half-wave supply.

Powering from 5V USB (MCP1700 SOT22) Thermal Calculations Max voltage drop required = 5.25-3.3=1.95V

Thermal resistance junction to ambient (JA) for MCP1700 SOT23A = 230 degrees C/W (from

Max case temperature = 150 degrees (from datasheet)

I max = (T case max – T ambient max)/thermal resistance (JA) / delta V max

I max (SOT23A) = ((150-40)/336)/1.95V = 168mA (for SOT23A)

The emonTx V3 does not support charging, please make sure batteries are removed before connecting USB or FTDI power.


For Power supply design circuit design see blog posts: [[1]] ][2]]

For emonTx V3 power supply specifications see: #Electrical Characteristics - Absolute min / max

All calcs assume using YHDC 013-000 CT and Ideal Power 9C AC-AC adapter 77DE-06-09-MI / 77DB-06-09-MI

A SOT89 MCP1754 LDO is use the the AC-DC power supply circuit. The MCP17542 can handle up to 16V input. The larger SOT89 package is needed to dissipate the heat. The large 47uF capacitor is needed to store enough energy to see us through half wave cycles. See section below for more info on AC-DC half wave operation.

The calculations below were first done for the MCP1702, this LDO was swapped for the Mcp1754. The MCP 1754 was used in the production version V3.2. See below for thermal calculations.

Powering from AC-DC half wave (MCP1702 SOT89) - old not used in production

Thermal resistance junction to ambient (JA) for MCP1702 SOT-89 JA=52 degrees C/W (from datasheet)

Max case temperature = 150 degrees (from datasheet)

I max = (T case max – T ambient max)/thermal resistance (JA) / delta V max

At 12Vrms (max output of 9V AC-AC at max mains voltage)

Delta B = 12-3.3 = 10.7V

I max (SOT-89) = ((150-40)/52)/10.7V = 21.6-19.7mA (30C – 40C ambient) worst case – max mains voltage and 50 degree ambient – max output = 18mA )

At V=10.4Vrms (output of 9V AC-AC at typical mains voltage)

Delta B = 10.4-3.3 = 7.1V

I max (SOT-89) = ((150-40)/52)/7.1V = 32.5-29.7mA (30C – 40C ambient)

At V=8.77Vrms (output of 9V AC-AC at min mains voltage)

Delta B = 8.77-3.3 = 3.62

I max (SOT-89) = ((150-40)/52)/3.62V = 63.7-58.4mA (30C – 40C ambient)

Assume maximum possible continuous current supplied by MCP1702 from AC-DC half-wave to be 18-20mA.

Powering from AC-DC half wave (MCP1754 SOT89) - new used in production V3.2

Thermal resistance junction to ambient (JA) for MCP1702 SOT-89 JA=153.3 degrees C/W (from datasheet P.22)

Max case temperature = 150 degrees (from datasheet)

I max = (T case max – T ambient max)/thermal resistance (JA) / delta V max

At 12Vrms (max output of 9V AC-AC at max mains voltage)

Delta B = 12-3.3 = 10.7V

I max (SOT-89) MCP1754 = ((150-40)/153.3)/10.7V = 67 mA (40C ambient)

worst case – max mains voltage and 50 degree ambient – max output = 61mA )

At V=10.4Vrms (output of 9V AC-AC at typical mains voltage)

Delta B = 10.4-3.3 = 7.1V

I max (SOT-89) MCP1754 = ((150-40)/153.3)/7.1V = 101 mA (40C ambient)

At V=8.77Vrms (output of 9V AC-AC at min mains voltage)

Delta B = 8.77-3.3 = 3.62

I max (SOT-89) MCP1754 = ((150-40)/153.3)/3.62V = 198 mA (40C ambient)

Using the MCP1754 with it’s higher thermal rating means the rating of the current limiting resistor is now the bottleneck factor in how much current can be drawn from the supply.

Robert Wall: AC-DC supply might not work (ripple will be unacceptable) if it is connected to a remote socket also serving a high current load at lowest mains voltage; however the possibility that this particular combination of circumstances will happen in practice is extremely remote and can be discounted.

AD-DC Power Supply Component ratings

Max operation output of circuit = 20mA

Max extreme output of circuit = 30mA - AC voltage sample will be affected and MCP1702 could overheat if ambient temperature is 40-50 degrees. 30MA should only be drawn for short periods. Eg SFR radio Tx'ing.

Do not try to draw more than 30mA. This will result in 3.3V rail significantly dropping and too higher current passing through 56R current limiting resistor. This will damage cause the resistor to heat up/burn out.

Halfwave rectifier diode D1: Worst case at highest mains voltage and extreme current output: 30mW average

Current limiting resistor: 56R R29. At worst case, lowest mains voltage and extreme current output: Average power dissipation: 222mW. 0.25W resistor will be ok.

Reservoir capacitor C18 47uF: should not see a higher voltage than 12V since the zener diode will clamp the voltage 12v. A capacitor rating of 16V will be more than enough.

De-coupling 1uF capacitor C17 voltage rating: The transformer is ground referenced, the other side referenced to 1.65 V – so 6.3 V should be plenty. The alternating component of the voltage should be very small, else we have phase shift problems. [The major part of the 12 V will appear across the divider chain, R13 + R14.]

Zener diode - 12V MCP1702 overvoltage protection 106mW average - not needed since MCP1754 is used and can handle 16V input

Open-Hardware Design Files

Proudly open source, the hardware designs are released under the Creative Commons Attribution-ShareAlike 3.0 Unported License:

All the Design files for the emonTx V3 are hosted on Git based SolderPad, see: http://solderpad.com/git/openenergymon/emontxv3

emonTx V3 BOM

Ideas for Future Versions

  • Add resistor divider (470K/1M with low value cap to GND) for battery voltage monitoring into free ADC, although there are no free ADC's! Maybe it could be jumpered into ADC0 since AC-AC will not be used when battery is preset?
  • Check optimal SMA antenna tuning PCB trace

Physical Dimensions

PCB: 100mm x 80mm

emonTx V3 Dimensions

Download: Extruded Aluminium Case Datasheet

Enclosure & Fascia CAD Design

It was decided to use an extruded aluminium case with acrylic fascia. The case is solid, wall mountable and port cutouts are easily customizable with laser cut fascias. The embodied energy of aluminium is greater than plastic to make in the first place but to recycle uses less energy than plastic. See our blog post investigating the embodied energy of casing materials.

The emonTx V3 fascia design CAD files are available here: Thingiverse Download

DIN Rail Mount

Thanks to @Aquefot for contributing a DIN mount rail fitting CAD design ready to be 3D printed for the emonTx: Thingiverse Download


The hardware designs (schematics and CAD files) are licensed under a Creative Commons Attribution-ShareAlike 3.0 Unported License.

The firmware is released under the GNU GPL V3 license

The documentation is subject to GNU Free Documentation License

The hardware designs follow the terms of the OSHW (Open-source hardware) Statement of Principles 1.0.

Environmental & Life Cycle

We are passionate about sustainability and are aware of the embodied energy and use of resources involved in electronic manufacture. We try our best to reduce environmental impact wherever possible:

  • We have recently been inspired by a few projects taking a lead in promoting and making steps towards Ethical and Sustainable Electronics, see our blog post we wrote on the topic .
  • The PCB's are manufactured in the UK by a manufacturer who uses lead free techniques, complies to the highest environmental industry standard and is actively investing in techniques and equipment to reduce wastage and environmental impact (e.g water treatment and recycling). Hot-air leveling was chosen instead of immersion gold finish to reduce environmental impact.
  • The assembly is also done in the UK with all components being RoHS compliant and free of conflict materials.
  • Surface freight is used in preference to air shipping when ordering parts in bulk. This consumes 33 times less energy.
  • We have strived to optimise electrical consumption in our hardware to be as low was possible and recommend the use of green rechargable batteries, see blog post



The OpenEnergyMonitor system is sold as a development kit to empower members of the openenergymonitor community to to get involved with the OpenEnergyMonitor open-source energy monitoring development project.

Your safety is your own responsibility, including proper use of equipment and safety gear, and determining whether you have adequate skill and experience. OpenEnergyMonitor and Megni registered partnership disclaims all responsibility for any resulting damage, injury, or expense. It is your responsibility to make sure that your activities comply with applicable laws, including copyright. Always check the webpage associated with each unit before you get started. There may be important updates or corrections! All use of the instructions, kits, projects and suggestions given both by megni.co.uk, openenergymonitor.org and shop.openenergymonitor.org are to be used at your own risk. The technology (hardware , firmware and software) are constantly changing, documentation (including build guide and instructions) may not be complete or correct.

If you feel uncomfortable with assembling or using any part of the kit, simply return it to us for a full refund.