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Making a 4 channel RF remote (PCB design included)

Making a 4 channel RF remote (PCB design included)

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In this article, Frank from Gadgetronicx website describes how to build a simple radio controlled remote.


Building a RF remote control is not a joke, even with dedicated TX, RX, encoder and decoder chips. I have attempted to build one and struggled quite a lot with it . This is because RF/ Wireless remote control circuits won’t work as expected always. There are number of things that could go wrong with it, I have finally cracked making a DIY remote control which am gonna share with you all.


To build this I have used HT12E, HT12D and 433Mhz RX and TX. Nothing fancy in it, these are quite common and you might have come across in many RF tutorials and circuits. There are list of problems you might face when building this remote control and I can certainly say that these issues are not straightforward to resolve.

  1. The decoder chip exhibits active state when powered ON, this will make the outputs active without any user input. This condition is totally undesirable since no one wants their device to get activated by itself without input feed.
  2. Unstable RF link will fluctuate thus in turn will cause abnormal operation.
  3. The active low behavior of HT12D will not allow you to drive output activators directly.
  4. The HT12D chip acts as a latch meaning that the output will not change it’s state unless there is new input fed to it. Imagine if you press a input button and release it, the output from the decoder will be latched and will remain the same even after you turn off the transmitter circuitry.


This is an encoder chip that has 4 data and 8 address lines for secured transmission. The input pins are active low, so will get activated only when you feed any low signal. Dout pin is where we will obtain encoded data. This will then go to TX module for transmission. Refer this “Working of HT12E” for more explanation on this chip.


This is a transmitter chip which uses ASK signalling scheme with the frequency of 433Mhz. This module is quite famous and can be found commonly with online vendors,


This is the matching decoder chip of HT12E. The output pins of this chip exhibits active low as already mentioned, so you cannot directly drive the activators using this chip. VT is a pin which goes high whenever valid transmission is received by the decoder. By the word valid I mean data signal with matching address set by the pins A0 to A8. We will be using this pin to identify whether a signal is received and this will help us in eliminating false trigger. Refer this “Working of HT12D” for more info on this chip.


This is the matching receiver to the TX which we saw earlier in this article.



The working of TX circuit is pretty straightforward and easy to understand. The 8 DIP SW1 switch connects the address lines to the ground on activation. This will enable user to set their desired address. Similarly I have added 4 DIP switches SW2 which will connect to ground and feeds data on activation since the data pins are active low. The TE pins controls whether the transmission of data from the chip. LED1 serves as an indicator when the board is ON. The 433Mhz TX module is connected to antenna. This module uses a DC jack or connector J3 for +5V power input.


Here is the PCB design of transmitter circuit. Here is the corresponding gerber files to this design which you can use to make your own PCB. You can download the design and PCB files from author’s website.



The receiver section of this project is of two sections Decoding (shown above) and Controlling part. In the above decoding section signal from the RX module, HT12D will decode the incoming signal. Use 8 DIP switch to set the address, remember this must be the same as encoder address for making successful reception. D6 lights up as an indication of successful signal reception from transmitter. You will now obtain the output data from the pins D8, D9, D10 and D11. This is a latch output so state of these pins will be remain same unless there is any change in the input signal to HT12E.





This is where things get tricky in this RF remote making and you might wanna pay close attention to this section. The main purpose of this section is to keep the output data stable , give power on reset pulse to prevent device from starting in undesired state, eliminate the effect of noisy signal and to give momentary remote control experience to the user.


The controlling section is of three separate blocks.

  1. RC Power on reset – R2C1
  2. Retriggerable multivibrator – IC1B, D1, C2, R3 and IC1C
  3. SR latch – IC2A and IC2B


The HT12D will start up with active state output which is undesirable. I am going to use signal from VT pin to eliminate this issue. This can be achieved with the help of SR latch using NOR gates IC2A, IC2B and NOT gate IC1A. Basically IC2A and IC2B forms a SR latch which is reset through NOT gate IC1A . At power ON C1 will be discharged so IC1A’s input will be low. C1 charges through R1 producing a high level which feeds high input to pin 1 of IC2A which is the reset pin of latch. This will reset the SR latch, from the above truth table we know that output of IC2A will be low and IC2B will be high when the system is ON. This will force low logic in all output pins of IC2C, IC2D,IC3A and IC3D which will be end output of this whole RF unit.



VT will give high signal output when there is a valid signal transmission from transmitter. Mostly the signal will be noisy which therefore fluctuates. So to derive a stable signal from VT, a retriggerable monostable multivibrator stage using IC1B, IC1C, D1, R3 and C2. Unstable VT signal will act as a trigger pulse, when VT is low output in IC1B goes high, which will charge the capacitor C2. When the capacitor is fully charged, the input to IC1C becomes high which in turn gives low as output. Similarly when VT goes high, the output of IC1B will be low which will discharge the capacitor through resistor R3 and once it’s done output of IC1C will switch to high state. The real magic lies with C2R3 pair which acts as a timing element in this circuit. And finally we will get stable VT signal as output.



The output from retriggerable mutlivibrator goes into Set pin of SR latch. Upon receiving valid data by the receiver, Set pin (pin 6 of IC2B) of SR latch will go high and this will result in low state output of IC2B. Remember Reset pin of SR latch that is 1st pin of IC2A would have been in logic 0 because of our Power on Reset pulse arrangement. Now that we have resolved the unstable VT signal, Power On reset and anonymous triggering of output all we have left is obtain the data in high logic so that it can drive components or activators.

The output from IC2B is used along with the actual Data output from the pins D8,D9, D10 and D11. Individual NOR gates like IC2C were used to combine the output of IC2B and D8. When AD8 is activated at the Encoder input, receiver will receive this signal decode them and exhibit it at D8 pin of the decoder which is active low. Upon successful reception output of IC2B will go low as explained above and combined with D8 which is active low using NOR gate IC2C. This in turn will give high output at output of IC2C which is the final output of D8 and can be used drive components or activators directly.

Similar things occur when AD8 is not activated at the encoder, D8 will be high therefore output of IC2C will be low. The same working principle applies for other data output pins. And your RF remote if finally ready to use.



This is the PCB design of the whole receiver circuit including the controlling unit. Connector J3 is where you could see the output pins and a Ground pin. This is to use this board with actuators and other microcontrollers. You can download all the schematic, design and gerber files for the receiver from author’s site.




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