Hearing Aid Circuit

Description 

Commercially available hearing aids are quite costly. Here is an inexpensive hearing aid circuit that uses just four transistors and a few passive components. 

Circuit Diagram

Parts:

• R1 = 2.2K
• R2 = 680K
• R3 = 3.3k
• R4 = 220K
• R5 = 1.5K
• R6 = 220R
• R7 = 100K
• R8 = 680K
• C1 = 104pF
• C2 = 104pF
• C3 = 1uF/10V
• C4 = 100uF/10V
• C5 = 100uF/10V
• Q1 = BC549
• Q2 = BC548
• Q3 = BC548
• Q4 = BC558
• J1 = Headphone jack
• B1 = 2x1.5V Cells
• SW1 = On/Off-Switch

Circuit Operation:

On moving power switch SW1 to ‘on’ position, the condenser microphone detects the sound signal, which is amplified by Q1 and Q2. Now the amplified signal passes through coupling capacitor C3 to the base of Q3.

The signal is further amplified by Q4 to drive a low impedance earphone. Capacitors C4 and C5 are the power supply decoupling capacitors. The circuit can be easily assembled on a small, general-purpose PCB or a Vero board.

It operates off a 3V DC supply. For this, you may use two small 1.5V cells. Keep switch S to ‘off’ state when the circuit is not in use. To increase the sensitivity of the condenser microphone, house it inside a small tube.

 Author: www.electronicsforu.com
  Source http://www.extremecircuits.net/2009/07/hearing-aid.html

07:52 0 comments

Three Channel Audio Splitter Circuit

Description 

This circuit is suitable to amplify and distribute the audio signals. The input audio signal is applied to the J1 and after passing through the P1, It is buffered and amplified by the IC1 prepared to redistribute. It has 3 outputs to drive 3 audio lines with 300 ohms impedance.

Circuit Diagram:

Parts:

• J1 = RCA Socket (See Notes)
• P1 = 100K-Potentiometre
• R* = 10K-100K
• R1 = 560K
• R2 = 1K
• R3 = 2.2K
• R4 = 2.7K
• R5 = 2.7K
• R6 = 330R
• R7 = 330R
• R8 = 330R
• C1 = 100uF-25V
• C2 = 100uF-25V
• C3 = 100uF-25V
• D1 = BZX79C18
• D2 = BZX79C18
• Q1 = BC337
• Q2 = BC327
• IC1 = NE5532-34 

Notes:

• J1 will be RCA Audio input female socket.
• R* is on your choice it can be choose between 10K to 100K resistor.
• Output capacitor’s value is between 100uf to 470uf and power handling is 25V to 50V.
• You can power up this circuit via +12V/-12V regulated supply but you have to remove following parts Q1-Q2-C2-C3-D1-D2.
• Maximum power ratings +35V/-35V

Source  http://www.extremecircuits.net/2009/07/3-channel-audio-splitter.html

08:35 0 comments

Multitone Siren Circuit

Description 

This multi-tone siren is useful for burglar alarms, reverse horns, etc. It produces five different audio tones and is much more ear-catching than a single-tone siren. The circuit is built around popular CMOS oscillator-cum-divider IC 4060 and small audio amplifier LM386. IC 4060 is used as the mult-itone generator. A 100µH inductor is used at the input of IC 4060. So it oscillates within the range of about 5MHz RF. IC 4060 itself divides RF signals into AF and ultrasonic ranges. Audio signals of different frequencies are available at pins 1, 2, 3, 13 and 15 of IC 4060 (IC1).

Circuit Diagram:

These multi-frequency signals are mixed and fed to the audio amplifier built around IC LM386. The output of IC2 is fed to the speaker through capacitor C9. If you want louder sound, use power amplifier TBA810 or TDA1010. Only five outputs of IC1 are used here as the other five outputs (pins 4 through 7 and 14) produce ultrasonic signals, which are not audible. Assemble the circuit on a general-purpose PCB and enclose in a suitable cabinet. Regulated 6V-12V (or a battery) can be used to power the circuit.

 Author: PradeeP G., Elektor Electronics Magazine
Source http://www.extremecircuits.net/2010/05/multitone-siren.html

06:05 0 comments

Sound Effects Generator Circuit

Description: 
 This circuit uses a UM3561 IC to produce four different sound effects.
Circuit Diagram

Notes:

 Nothing too complicated here. The IC produces all the sound effects, the output at Pin 3 being amplified by the transistor. A 64 ohm loudspeaker can be substituted in place of the 56 ohm resistor and 8 ohm loudspeaker. The 2 pole 4 way switch controls the sound effects. Position 1 (as drawn) being a Police siren, position 2 is a fire engine sound, 3 is an ambulance and position 4 is a machine gun effect. The IC is manufactured by UMC and was available from Maplin electronics code UJ45Y. At the time of writing this has now been discontinued, but they have have limited stocks available.

Author: Andy Collinson, anc@mitedu.freeserve.co.uk
Source http://www.zen22142.zen.co.uk/

06:13 0 comments

Loudspeaker Protection 2 for P.A output

Description 

The circuit protection output of power amplifiers and loudspeakers, dispose certain interesting elements, as the isolation of loudspeakers from the exit of amplifier, when is presented continuous voltage in his exit or when the temperature of heatsink, goes up excessively, providing simultaneously and time delay in the connection loudspeakers in the amplifier, so that we avoid pass in them, the known annoying noises from the charge - discharge of capacitors of supply. It’s constituted by a binary comparator [ IC1 ], the transistors Q1-2 and indicative LED D5-6. The supply of circuit can become from positive voltage [ Point A ] of mainly power supply, which is stabilised by the D3 and the R17, in + 15V. Point B is connected in one of the secondary AC coil of main transformer. If close the main switch of main line AC, then a AC voltage (in secondary coil of transformer), is presented in the point B, it’s rectified from the D2 and it supply with negative voltage, via the R9, the Q3, this cut off and it begin charge the C4 via the R10-11. As long as time therefore last the charge of capacitor, the input [+] of comparator IC2B is found in low level concerning input [-]. The exit of IC2B, has low level, therefore the Q4 remain in cutt off and the RL1 remain deactivate, the D6 he is ON. Just the C4 charged, change the situation of IC1B, is activated the RL1, the loudspeaker are connected in the amplifier output, the D6 it OFF. When it’s interrupted the supply, all the process is inverted, and the loudspeaker disconnect, without pass annoying noises. If as long as it work the circuit, is presented problem of continuous voltages in the exit of amplifier then turn off of RL1 and protected the loudspeakers. This become with help the Q1-2. The acoustic signal from the exit of power amplifier, is led to point D, the alternate voltages is led to the ground via the C1-2, that create a not polar capacitor. Continuous voltages, bigger than + 1.7V or smaller than –4.8V, activate immediately the Q1 or the Q2, respectively. With the activation of transistors goes down the level of input [+] of IC1B, so that turn off and the RL1. A other section of protection that for us provide the circuit is the thermic protection. This become with the help of sensor temperature the RTH, which is a resistor of type PTC (positive factor of temperature), and is found placed above in heatsink, where are found also the power transistors. Her price increase, with the increase of temperature, until the potential in input [-] of IC1A, goes up above from the level of input [+], which is determined with the voltage divider R2-3. As soon as the level in input [-] exceed the level of input [+], the exit of IC1A, it return in low level, compelling and the IC2B to change situation, turn off the RL1 and to turn on the D5, that show the thermic protection. In the circuit the limit above which it exist clue of thermic protection they are 70?C. If it’s presented instability, in this stage, in operation of RL1, should be changed the R4, with other of smaller price. The circuit was published in magazine “Elektor” 12/95. 

Circuit Diagram

Part List

• R1-2=27 Kohms
• R3=1.4 Kohms
• R4=1 Mohms
• R5-14-17=3.3 Kohms
• R6-7=100 Kohms
• R8=47 Kohms
• R9-11=120 Kohms
• R10=470 Kohms
• R12=15 Kohms
• R13=1.5 Kohms
• R15=4.7 Kohms
• R16=33 Kohms
• R18=1.5 Kohms 5W
• RTH=KTY81-122
• C1-2=100uF 63V
• C3=470nF 100V MKT
• C4-5=47uF 25V
• IC1=LM393
• Q1-2-3=BC337
• Q4=BC639
• D1=1N4148
• D2=1N4004
• D3=15V 1.5W Zener
• D4=1N4002
• D5-6=LED
• RL1=24V Relay 

Source -http://users.otenet.gr/~athsam/protection_2_EN.htm

06:47 0 comments