Full-duplex Intercom

No complex switching required
Simple circuitry, 6-12V supply

This design allows to operate two intercom stations leaving the operator free of using his/her hands in some other occupation, thus avoiding the usual "push-to-talk" operation mode.
No complex changeover switching is required: the two units are connected together by means of a thin screened cable.

As both microphones and loudspeakers are always in operation, a special circuit is used to avoid that the loudspeaker output can be picked-up by the microphone enclosed in the same box, causing a very undesirable and loud "howl", i.e. the well known "Larsen effect".
A "Private" switch allows microphone muting, if required.


Circuit operation:

The circuit uses the TDA7052 audio power amplifier IC, capable of delivering about 1 Watt of output power at a supply voltage comprised in the 6 - 12V range.
The unusual feature of this design is the microphone amplifier Q1: its 180° phase-shifted audio output taken at the Collector and its in-phase output taken at the Emitter are mixed by the C3, C4, R7 and R8 network and R7 is trimmed until the two incoming signals almost cancel out. In this way, the loudspeaker will reproduce a very faint copy of the signals picked-up by the microphone.

At the same time, as both Collectors of the two intercom units are tied together, the 180° phase-shifted signal will pass to the audio amplifier of the second unit without attenuation, so it will be loudly reproduced by its loudspeaker.

The same operation will occur when speaking into the microphone of the second unit: if R7 will be correctly set, almost no output will be heard from its loudspeaker but a loud and clear reproduction will be heard at the first unit output.

Parts:

• P1_____________22K Log. Potentiometer
• R1_____________22K 1/4W Resistor
• R2,R3_________100K 1/4W Resistors
• R4_____________47K 1/4W Resistor
• R5______________2K2 1/4W Resistor (See Notes)
• R6______________6K8 1/4W Resistor
• R7_____________22K 1/2W Carbon or Cermet Trimmer
• R8______________2K7 1/4W Resistor
• C1,C6_________100nF 63V Polyester or Ceramic Capacitors
• C2,C3__________10µF 63V Electrolytic Capacitors
• C4_____________22µF 25V Electrolytic Capacitor
• C5_____________22nF 63V Polyester or Ceramic Capacitor
• C7____________470µF 25V Electrolytic Capacitor
• Q1____________BC547 45V 100mA NPN Transistor
• IC1_________TDA7052 Audio power amplifier IC
• SW1____________SPST miniature Switch
• MIC____________Miniature electret microphone
• SPKR___________8 Ohm Loudspeaker
• Screened cable (See Text)

Notes:

• The circuit is shown already doubled in the diagram. The two units can be built into two separate boxes and connected by a thin screened cable having the length desired.
• The cable screen is the negative ground path and the central wire is the signal path.
• The power supply can be a common wall-plug adapter having a voltage output in the 6 - 12V dc range @ about 200mA.
• Enclosing the power supply in the box of one unit, the other unit can be easily fed by using a two-wire screened cable, its second wire becoming the positive dc path.
• To avoid a two-wire screened cable, each unit may have its own separate power supply.
• Please note that R5 is the only part of the circuit that must not be doubled.
• Closing SW1 prevents signal transmission only, not reception.
• To setup the circuit, rotate the volume control (P1) of the first unit near its maximum and speak into the microphone. Adjust Trimmer R7 until your voice becomes almost inaudible when reproduced by the loudspeaker of the same unit.
• Do the same as above with the second unit.

Telephone call Voice Changer

Voice manipulation device specially intended for props
9V Battery operation

Although this kind of voice effect can be obtained by means of some audio computer programs, a few correspondents required a stand-alone device, featuring microphone input and line or loudspeaker outputs.

This design fulfills these requirements by means of a variable gain microphone preamplifier built around IC1A, a variable steep Wien-bridge pass-band filter centered at about 1KHz provided by IC1B and an audio amplifier chip (IC2) driving the loudspeaker.


Parts:

• P1______________10K Log. Potentiometer
• R1,R10__________10K 1/4W Resistors
• R2_______________1K 1/4W Resistor
• R3______________50K 1/2W Trimmer Cermet or Carbon
• R4,R6,R7,R14___100K 1/4W Resistors
• R5______________47K 1/4W Resistor
• R8______________68K 1/4W Resistor
• R9_______________2K2 1/2W Trimmer Cermet or Carbon
• R11_____________33K 1/4W Resistor
• R12_____________18K 1/4W Resistor
• R13_____________15K 1/4W Resistor
• C1,C2,C3,C8,C9_100nF 63V Polyester Capacitors
• C4______________10µF 25V Electrolytic Capacitor
• C5_____________220nF 63V Polyester Capacitor (Optional, see Notes)
• C6_______________4n7 63V Polyester Capacitor
• C7______________10nF 63V Polyester Capacitor
• C10____________220µF 25V Electrolytic Capacitor
• IC1___________LM358 Low Power Dual Op-amp
• IC2_________TDA7052 Audio power amplifier IC
• MIC1__________Miniature electret microphone
• SPKR______________8 Ohm Small Loudspeaker
• SW1____________DPDT Toggle or Slide Switch
• SW2,SW3________SPST Toggle or Slide Switches
• J1____________6.3mm or 3mm Mono Jack socket
• B1_______________9V PP3 Battery (See Notes)
• Clip for PP3 Battery

Notes:

• The pass-band filter can be bypassed by means of SW1A and B: in this case, a non-manipulated microphone signal will be directly available at the line or loudspeaker outputs after some amplification through IC1A.
• R3 sets the gain of the microphone preamp. Besides setting the microphone gain, this control can be of some utility in adding some amount of distortion to the signal, thus allowing a more realistic imitation of a telephone call voice.
• R9 is the steep control of the pass-band filter. It should be used with care, in order to avoid excessive ringing when filter steepness is approaching maximum value.
• P1 is the volume control and SW2 will switch off amplifier and loudspeaker if desired.
• C5 is optional: it will produce a further band reduction. Some people think the resulting effect is more realistic if this capacitor is added.
• If the use of an external, moving-coil microphone is required, R1 must be omitted, thus fitting a suitable input jack.
• This circuit was intended to be powered by a 9V PP3 battery, but any dc power supply in the 6 - 12V range can be used successfully.

Intercom with fader

Suitable for tandem bicycles and motor cycles
Connects to iPod and similar MP3 audio players

A project of this kind was requested by a couple riding a tandem bicycle and looking for a device to install all in one box, allowing them to talk. Furthermore, they liked the option to plug an iPod in as well and having it mute automatically when one of them was speaking.



Parts:

• R1,R2___________22K 1/4W Resistor
• R3,R20___________1K 1/4W Resistors
• R4______________50K 1/2W Trimmer Cermet or Carbon
• R5______________47K 1/4W Resistor
• R6,R7,R8_______100K 1/4W Resistors
• R9,R10__________68K 1/4W Resistors (See Comments)
• R11,R15,R16______1M 1/4W Resistors
• R12____________470K 1/4W Resistor (See Comments)
• R13,R14________220K 1/4W Resistors
• R17,R18________100K 1/4W Resistors
• R19____________470R 1/4W Resistor
• C1,C2,C5,C7,C8_100nF 63V Polyester or Ceramic Capacitors
• C3_____________100nF 63V Polyester or Ceramic Capacitor (See Notes)
• C4,C6___________10µF 25V Electrolytic Capacitors
• C9_____________100µF 25V Electrolytic Capacitor
• C10____________220µF 25V Electrolytic Capacitor
• C11____________470µF 25V Electrolytic Capacitor
• D1,D2________1N4148 75V 150mA Diodes
• Q1____________BC560C 45V 100mA Low noise High gain PNP Transistor
• Q2____________BC550C 45V 100mA Low noise High gain NPN Transistor
• Q3,Q6_________BC337 45V 800mA NPN Transistors
• Q4,Q5_________BC327 45V 800mA PNP Transistors
• IC1___________LM358 Low Power Dual Op-amp
• IC2____________4016 or 4066 Quad bilateral switch IC
• J1,J2___________3mm Mono Jack sockets
• J3,J4,J5________3mm Stereo Jack sockets
• SW1____________SPST Toggle or Slider Switch
• B1_______________6V Battery (4 x AA or AAA 1.5V Cells in series
• or any 6V rechargeable battery pack etc.)

Circuit operation:

The complete circuit is shown in the diagram and is formed by a microphone amplifier built around IC1A, a simple ac-dc converter (IC1B and related components) driving the dual electronic switch (IC2A and IC2B) and a headphone amplifier formed by Q1 - Q6 etc. For this amplifier only the left channel is shown: obviously, the right channel will be identical (input and output connections are shown into the rectangular box).

The two microphones (small electret types) are connected to J1 and J2 and the two headphone sets (usually 32 Ohms impedance) to J4 and J5. The iPod headphone output is connected to J3 by means of suitable stereo cable and 3mm jack plugs. There is no volume control: the desired level of the music programme is adjusted by means of the iPod control.

R4 acts as a volume control for the microphones and also sets the threshold at which the music will be muted: it should be set once for all and then left alone. As a matter of fact, the music will not disappear completely: it will be attenuated by about 10.5dB if a 68K value is used for R9 and R10 whereas a 100K value will cause an attenuation of about 8dB. In practice, the lesser the value of R9 and R10 the higher the attenuation of the music.

When speaking is stopped, the music will revert to full volume after some time-delay, set by R12 and C6. The value of these components can be varied to suit one's own needs. The headphone amplifiers, despite the high number of transistors used, are simple enough, efficient and, above all, setup-free. They are able to deliver a full 5V peak-to-peak sinewave into 16 Ohm (i.e. about 200mW into two 32 Ohm headphones wired in parallel) with less than 1% distortion @ 1KHz and 0.7% @ 10KHz. At the standard 40mW headphone power output capability, distortion figures are 0.6% @ 1KHz and 0.3% @ 10KHz.

Notes:

• Sometimes, the use of only one microphone could be desirable. In this case, plug the microphone jack into J1 or J2, but plug a "dummy jack" without cable into the other socket as well.
• The tone of the microphone channel can be made more "warm" by increasing C3 value to 1µF or more. In this case pay attention, as microphones could pick-up unwanted low frequency motor or traffic noise, causing the activation of the mute circuit even in the absence of speaking.
• Please note that the control pins of the unused bilateral switches contained into IC2 must be wired to negative ground. Other pins can be left open as shown in the diagram, bottom right.

Remote Telephone Ringer

This remote telephone bell ringer allows you to use a large (and loud) external bell in place or in addition to the built in (and rather wussy) ringer in most modern telephones. This is ideal for large outdoor areas, noisy shops or those hard of hearing. Most any large bell can be used as the circuit can be easily adjusted for various supply voltages.

Parts List

• C1- 0.47 300V Capacitor
• C2 - 47uF 25V Electrolytic Capacitor
• R1 - 1K 1/4W Resistor
• R2 - 10K 1/4W Resistor
• R3 - 1K Pot
• R4 - 2K 1/4W Resistor
• Q1 - 6A, 200V TRIAC
• Q2 - 6A, 200V SCR (106, Etc.)
• D1 - 1N4774 Zener Diode
• D2, D3- 1N4007 Rectifier Diode
• U1- 4N33 Opto Isolator
• Bell - Large Bell (Fire Bell, School Bell, Etc.)
• Misc.- Board, Wire, Socket For U1, Case

Notes

1. Virtually any TRIAC and SCR will work for Q1 and Q2 as long as the voltage rating is high enough. Q2 needs enough current capacity to handle the full load of the bell.
2. To adjust R3, call the phone line on which the ringer is installed and adjust the pot until the bell begins to sound consistently.
3. Make sure to check with local authorities before you connect a homemade device to your phone lines. Some areas mandate that only approved devices can be connected to the loop. This circuit provides an opto-isolator to prevent cosstalk between the phone line and power supply as well as to avoid ground loops.