Using this low-cost project one can reproduce audio from TV without disturbing others. It does not use any wire connection between TV and Loud Speaker. In place of a pair of wires, it uses invisible infra-red light to transmit audio signals from TV to Loud speakers, Without using any lens a range of up to 6 meters is possible. Range can be extended by using lenses and reflectors with IR sensors comprising transmitters and receivers.
Transmitter's operation:
IR transmitter uses two-stage transistor amplifier to drive two series-connected IR LEDs. An audio output transformer (T1) is used (in reverse) to couple audio output from TV to the IR transmitter. Transistors Q1 and Q2 amplify the audio signals received from TV through the audio transformer. Low impedance output windings (lower gauge or thicker wires) are used for connection to TV side while high-impedance windings are connected to IR transmitter. This IR transmitter can be powered from a 9V mains adapter or a 9V battery. Red LED (D1) in transmitter circuit functions as a Zener diode (0.65V) as well as supply-on indicator.
IR transmitter uses two-stage transistor amplifier to drive two series-connected IR LEDs. An audio output transformer (T1) is used (in reverse) to couple audio output from TV to the IR transmitter. Transistors Q1 and Q2 amplify the audio signals received from TV through the audio transformer. Low impedance output windings (lower gauge or thicker wires) are used for connection to TV side while high-impedance windings are connected to IR transmitter. This IR transmitter can be powered from a 9V mains adapter or a 9V battery. Red LED (D1) in transmitter circuit functions as a Zener diode (0.65V) as well as supply-on indicator.
Transmitter diagram:
Wireless Audio Power Amplifier Transmitter Circuit Diagram
Receiver's operation:
IR receiver uses popular op-amp IC µA741 and audio-frequency amplifier IC LM386 along with phototransistor L14F1 (Q3) and some discrete components. The sound generated by TV set is transmitted through IR LEDs, received by phototransistor Q3 and fed to pin 2 of IC µA741 (IC1). Its gain can be varied using potmeter P2. The output of IC µA741 is fed to IC LM386 (IC2) via capacitor (C7) and potmeter P3. The sound produced is heard through the receiver’s loudspeaker. Potmeter P3 is used to control the volume of loudspeaker SPKR (8-ohm, 1W).
Receiver diagram:
Wireless Audio Power Amplifier Transmitter Circuit Diagram
Parts:
P1 = 10K
P3 = 10K
P2 = 1M
R1 = 4.7K
R2 = 22K
R3 = 100R
R4 = 10R-1W
R5 = 10K
R6 = 10K
R7 = 15K
R8 = 15K
R9 = 100K
R10 = 680R-1W
R11 = 1K
R12 = 10R-1W
C1 = 220uF-25V
C2 = 220uF-25V
C3 = 10uF-25V
C4 = 220uF-25V
C5 = 220uF-25V
C6 = 100nF-63V
C7 = 100nF-63V
C8 = 100nF-63V
C9 = 100nF-63V
D1 = Red LED
D2 = IR LEDs
D3 = IR LEDs
Q1 = BC547
Q2 = BD140
Q3 = L14F1
IC1 = uA741 Opamp
IC2 = LM386
J1 = Audio input Jack
T1 = Audio Transformer
SPKR = 1W-8ohm
P1 = 10K
P3 = 10K
P2 = 1M
R1 = 4.7K
R2 = 22K
R3 = 100R
R4 = 10R-1W
R5 = 10K
R6 = 10K
R7 = 15K
R8 = 15K
R9 = 100K
R10 = 680R-1W
R11 = 1K
R12 = 10R-1W
C1 = 220uF-25V
C2 = 220uF-25V
C3 = 10uF-25V
C4 = 220uF-25V
C5 = 220uF-25V
C6 = 100nF-63V
C7 = 100nF-63V
C8 = 100nF-63V
C9 = 100nF-63V
D1 = Red LED
D2 = IR LEDs
D3 = IR LEDs
Q1 = BC547
Q2 = BD140
Q3 = L14F1
IC1 = uA741 Opamp
IC2 = LM386
J1 = Audio input Jack
T1 = Audio Transformer
SPKR = 1W-8ohm