By chauhannaman98 Follow
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Wireless Audio is already a technically advanced field where Bluetooth and RF Communications are the main technologies (although most commercial audio equipment works with Bluetooth). Designing a simple IR Audio Link Circuit would not be beneficial when compared to the existing technologies but it surely will be a learning experience about the wireless audio transfer.
The reason for not being beneficial is the fact that unlike Bluetooth, IR is line-of-sight communication i.e. both the transmitter and receiver must always face each other without any obstacles. Also, the range may not the as large as that of a typical Bluetooth Wireless Audio.
None the less, for the purpose of understanding, let me design a simple IR Audio Link circuit using easily available components.
This project is sponsored by LCSC. I have been using electronic components from LCSC.com. LCSC has a strong commitment to offering a wide selection of genuine, high-quality electronic components at the best price. Sign up today and get $8 off on your first order.
The principle behind the circuit is that we will have two individual circuits. One is the transmitter circuit and the other is the receiver circuit, the transmitter circuit will be connected to the 3.5 mm Audio jack for audio input and the receiver circuit will be connected to a speaker to play the songs. The Audio signal will be transmitted through an IR LED from the transmitter circuit; the IR signals will be then received by a photodiode which will be placed on the receiver circuit. The audio signal thus received by the photodiode will be very weak and hence it will be amplified by an LM386 amplifier circuit and finally played on a speaker.
It is very similar to your TV remote, when you press a button the IR led at the front of your TV, it transmits a signal which will be picked up by a photodiode (TSOP commonly) and the signal will be decoded to find which button you have pressed, check here the universal IR remote using TSOP. Similarly here the signal transmitted will be an audio signal and the receiver will be a plain photodiode. This technique will also work with normal LEDs and solar panels; you can read the Audio Transfer using Li-Fi article to understand how this method is very similar to Li-Fi technology.
The transmitter circuit only consists of a couple of IR LEDs and resistor connected directly to the audio source and the battery. One tricky place where you might encounter a problem is with connecting the audio jack to the circuit. A normal Audio jack will have three output pins two for left and right earphone and the other is a shield which will act as a ground. We need one signal pin which can be either left or right and one ground pin for our circuit. You can use a multimeter in connectivity to find the right pinouts.
The working of the Transmitter circuit is pretty simple, the IR light from the IR LED acts as a carrier signal and the intensity of the IR light acts as a modulating signal. So if we power the IR led through an Audio source the battery will illuminate the IR led and the intensity with which it glows will be based on the audio signal. We have used two IR LEDs here just to increase the range of the circuit; otherwise, we can use even one. I build my circuit over a breadboard and the circuit can be powered anywhere between 5V to 9V, I used a regulated 5V in place of the battery so I did not use the current limiting resistor 1K. The breadboard setup is shown below, I have connected my iPod here as an audio source but can use anything that has an Audio jack (Sorry iPhone users).
The receiver circuit consists of a photodiode which is connected to an Audio amplifier circuit. The Audio amplifier circuit is built using the popular LM386 IC from Texas Instruments, the advantage of this circuit is that its minimum requirement of components. This circuit can also be powered from a voltage ranging from 5V to 12 V, I have used my breadboard regulator module to supply +5V to the circuit but you can also use a 9 V battery as well.
PIN 1 and 8: These are the gain control PINs, internally the gain is set to 20 but it can be increased up to 200 by using a capacitor between PIN 1 and 8. We have used 10uF capacitor C3 to get the highest gain i.e. 200. Gain can be adjusted to any value between 20 to 200 by using the proper capacitor.
Pin 2 and 3: These are the input PINs for sound signals. Pin 2 is the negative input terminal, connected to the ground. Pin 3 is the positive input terminal, in which the sound signal is fed to be amplified. In our circuit, it is connected to the positive terminal of the condenser mic with a 100k potentiometer RV1. Potentiometer acts as a volume control knob.
Pin 4 and 6: These are the power supply Pins of IC, Pin 6 for is +Vcc and Pin 4 is Ground. The circuit can be powered with the voltage between 5-12v.
Pin 5: This is the output PIN, from which we get the amplified sound signal. It is connected to the speaker through a capacitor C2 to filter DC coupled noise.
Pin 7: This is the bypass terminal. It can be left open or can be grounded using a capacitor for stability.
For people who didn't get it working the first time, follow the steps to debug the circuit.