Programmable LED Indicator

Although IC CD4017 is a decade counter, it can be used in a variety of ways. In this circuit it has been used to program a bicolour LED indicator in 10 different modes which can be selected with a single push-button switch. IC3(555) is used in astable mode to generate square wave and transistor T1 is used to obtain its complementary waveform. IC2 CD4081 is a quad 2-input AND gate. These AND gates and the diode atrix

form the logical part of the circuit. IC4 (555) is configured as a monostable flipflop which provides a single clock pulse to IC1 CD4017 for changing the mode by depression of push-to-on switch S1. The use of IC4 avoids switch debouncing problem which causes multiple makes/breaks.

Switch S2 is included for resetting the circuit. Instead of just one bicolour LED you can use an array of bicolour LEDs in conjunction with two driver transistors. The bicolour (RED and GREEN) LED has three legs. The middle terminal (pin2) LED is the common cathode pin which is grounded when a positive voltage is applied to pin1, it emits red light. Similarly, when positive voltage is applied to pin3, it emits green light. And when positive voltage is simultaneously applied to its pin1 and 3, it emits yellowish light. Power supply used is +5V regulated. Various modes of this circuit are summerised in Table I. Outputs of IC1 can also be selected through a 10-way rotary switch connected to Vcc. Now IC1 can be eliminated. Different indications can be activated for different functions of a device. Construction is very easy and total cost of this circuit is less than Rs 60. Current consumption of the circuit is less than 100mA.

Download Full Circuit

Antenna Handbook Vol.3 Applications

Antenna Handbook Vol.3 Applications

Antenna Handbook Vol.2 Theory

Antenna Handbook Vol.2 Theory

Antenna Handbook Vol.1 Fundamentals and Mathematical Techniques

Antenna Handbook Vol.1 Fundamentals and Mathematical Techniques

MULTI-MELODY GENERATOR WITH INSTRUMENTAL EFFECT

This melody generator can generate various English and Hindi tunes as also instrumental effects. Various modes of melodies can be selected through DIP switches. Other advantages are high volume and volume control. IC UM3481A is a 16-pin multi-instrument melody generator. It is a mask-ROM-programmed IC designed to play the melody according to the programmed data. Its inbuilt preamplifier provides a simple interface to the driver circuit. The IC can be replaced with other UM348XXX series, WR630173 or E4822 melody generator ICs. A WR630173 preprogrammed as Hindi melody generator can be used here. There are 16 tunes stored in WR630173 including mera joota hai japani, mera naam chin chin chu, hare rama hare

krishna, raghu pati raghav raja ram and ramaiya vasta vaiya.

The circuit is powered by a 3V battery. Switch S2 is the main input-select switch for producing different tones in the loudspeaker. Various modes of operation are selected through DIP switches S3, S4 and S5 connected to pins 3, 5 and 7 of IC1, respectively. Pin 7 is the envelope circuit terminal through which instrumental effects are produced. The preamplifier outputs are available at pins 10 and 11, which are fed to loudspeaker- driver transistors T1 (SK100) and T2 (SL100), respectively. When you switch on the circuit by closing switch S1, LED1 glows. If DIP switches S3 and S5 are closed and S4 open, pressing input switch S2 will generate a melody tone from the loudspeaker. Vary VR1 to adjust its volume. Pressing S2 again will generate a new melody tone. If switches S3 and S4 are opened while S5 is closed, the same tone keeps repeating for every pressing of S2. The positions of DIP switches and the various modes of melodies are summarised in the table. When switch S5 is open, it will generate an instrumental effect from the loudspeaker. This effect is produced by the enveloping circuit consisting of capacitor C1 and resistor R2 connected to pin 7 of IC1. In fact, by hit and trial you can choose the values of these components as per your taste by listening to the output sound. Only C1 or R2 or its parallel combination can be used to generate a distinct instrument effect. To select any of these options, two jumper terminals J1 and J2 are provided in the circuit at C1 and R2, respectively. For example, if you want to use only C1, you can join J1 terminals using hookup wire or jumper cap and keep J2 open. The repetition of the musical effect depends on the status of switches S3 and S4. The oscillation frequency is produced by the resistor and capacitor connected at pins 14 and 13 of IC1. This frequency is used as a time base for the tone, rhythm and tempo generators.

The quality of the melody tones depends on this frequency. Resistor R6 (100-kilo-ohm) connected to pin 15 makes the circuit insensitive to variations in the power supply.

Download Full Circuit

Power Electronics Handbook - RASHID, M. H.

Publisher: Academic Press
Number Of Pages: 1000
Publication Date: 2001-08-24
Sales Rank: 613920
ISBN / ASIN: 0125816502
EAN: 9780125816502
Binding: Hardcover
Manufacturer: Academic Press

Power electronics is a broad subject that deals with every aspect of electronic systems and devices. Any computer, machine, controller, game, etc., that is available today is dependent on the power electronics in those systems and devices to operate. Power electronics systems deal with the process of converting electrical power from one form to another. Power Electronics Handbook is specifically designed for the professional engineer in industry and includes contributions of over 60 authors primarily from industry.

Download Full Book

First Course on Power Electronics and Drives - Ned Mohan

ISBN: 0971529221

Title: First Course on Power Electronics and Drives

Author: Ned Mohan

Publisher: MNPERE

Publication Date: 2003-07-15

Number Of Pages: 248

Designed with undergraduate students in mind who are likely to take only one course on this subject:

-Prepare them for industry

-Impart fundamentals and provide a roadmap for life-long learning

-Provide breadth and depth in less than 250 pages

-Based on feedback from over 350 faculty members at workshops in 1991, 1994, 1997, 1998, 2002 and 2003.

Download Full Book

Electric Power Distribution Equipment and Systems

Electric Power Distribution Equipment and Systems
By Thomas Allen Short
* Publisher: CRC
* Number Of Pages: 344
* Publication Date: 2005-11-29
* ISBN / ASIN: 0849395763

Book Description:
Practitioner Short has selected chapters from Electric Power Distribution Handbook to create this concise, focused reference on the technologies and infrastructure necessary for power distribution along vast distances as well as to local customers. Topics of those chapters include the fundamentals of distribution systems, including urban networks, distribution substations, and differences between European and North American systems; overhead lines, including typical constructions, simplified line impedance calculations, and fault withstanding capacity; underground distribution, including applications, cables, cable testing and fault location; transformers, including single-phase, three-phase, special transformers and loadings; voltage regulation, including techniques, regulators and station regulation; and capacitor application, including reducing line losses and caring for failure and case ruptures.

Download Full Book

Electric Machinery

Electric Machinery

By A. E. Fitzgerald,&nbspJr., Charles Kingsley,&nbspStephen D. Umans,&nbspStephen Umans,

* Publisher: McGraw-Hill Science/Engineering/Math

* Number Of Pages: 704

* Publication Date: 2002-07-25

* ISBN / ASIN: 0073660094

Book Description: 

The exciting new sixth edition of Electric Machinery has been extensively updated while retaining the emphasis on fundamental principles and physical understanding that has been the outstanding feature of this classic book. This book covers fundamental concepts in detail as well as advanced topics for readers who wish to cover the material in more depth. Several new chapters have been added, including a chapter on power electronics, as well as one on speed and torque control of dc and ac motors. This edition has also been expanded with additional examples and practice problems.

Download Full Book

Modern Antenna Design, 2nd Edition - Thomas

Modern Antenna Design, 2nd Edition - Thomas A. Milligan

Download Full Book

Antenna Engineering Handbook - 3ed - Johnson

Download Full Book

Automatic Room Power Control

An ordinary automatic room power control circuit has only one light sensor. So when a person enters the room it gets one pulse and the lights come ‘on.’ When the person goes out it gets another pulse and the lights go ‘off.’ But what happens when two persons enter the room, one after the other? It gets two pulses and the lights remain in ‘off’ state. The circuit described here overcomes the above-mentioned problem. It has a small memory which enables it to automatically switch ‘on’ and switch ‘off’ the lights in a desired fashion.

The circuit uses two LDRs which are placed one after another (separated by a distance of say half a metre) so that they may separately sense a person going into the room or coming out of the room. Outputs of the two LDR sensors, after processing, are used in conjunction with a bicolour LED in such a fashion that when a person gets into the room it emits green light and when a person goes out of the room it emits red light, and vice versa. These outputs are simultaneously applied to two counters. One of the counters will count as +1, +2, +3 etc when persons are coming into the room and the other will count as -1, -2, -3 etc when persons are going out of the room. These counters make use of Johnson decade counter CD4017 ICs. The next stage comprises two logic ICs which can combine the outputs of the two counters and determine if there is any person still left in the room or not. Since in the circuit LDRs have been used, care should be taken to protect them from ambient light. If desired, one may use readily available IR sensor modules to replace the LDRs. The sensors are installed in such a way that when a person enters or leaves the room, he intercepts the light falling on them sequentially—one after the other. When a person enters the room, first he would obstruct the light falling on LDR1, followed by that falling on LDR2. When a person leaves the room it will be the other way round. In the normal case light keeps falling on both the LDRs, and as such their resistance is low (about 5 kilo-ohms). As a result, pin 2 of both timers (IC1 and IC2), which have been configured as monostable flip-flops, are held near the supply voltage (+9V). When the light falling on the LDRs is obstructed, their resistance becomes very high and pin 2 voltages drop to near ground potential, thereby triggering the flip-flops. Capacitors across pin 2 and ground have been added to avoid false triggering due to electrical noise. When a person enters the room, LDR1 is triggered first and it results in triggering of monostable IC1. The short output pulse immediately charges up capacitor C5, forward biasing transistor pair T1-T2. But at this instant the collectors of transistors T1 and T2 are in high impedance state as IC2 pin 3 is at low potential and diode D4 is not conducting. But when the same person passes LDR2, IC2 monostable flip-flop is triggered. Its pin 3 goes high and this potential is coupled to transistor pair T1-T2 via diode D4. As a result transistor pair T1-T2 conducts because capacitor C5 retains the charge for some time as its discharge time is controlled by resistor R5 (and R7 to an extent). Thus green LED portion of bi-colour LED is lit momentarily. The same output is also coupled to IC3 for which it acts as a clock. With entry of each person IC3 output (high state) keeps advancing. At this stage transistor pair T3-T4 cannot conduct because output pin 3 of IC1 is no longer positive as its output pulse duration is quite short and hence transistor collectors are in high impedance state. When persons leave the room, LDR2 is triggered first, followed by LDR1. Since the bottom half portion of circuit is identical to top half, this time, with the departure of each person, red portion of bicolour LED is lit momentarily and output of IC4 advances in the same fashion as in case of IC3. The outputs of IC3 and those of IC4 (after inversion by inverter gates N1 through N4) are ANDed by AND gates (A1 through A4) and then wire ORed (using diodes D5 through D8). The net effect is that when persons are entering, the output of at least one of the AND gates is high, causing transistor T5 to conduct and energise relay RL1. The bulb connected to the supply via N/O contact of relay RL1 also lights up. When persons are leaving the room, and till all the persons who entered the room have left, the wired OR output continues to remain high, i.e. the bulb continues to remains ‘on,’ until all persons who entered the room have left. The maximum number of persons that this circuit can handle is limited to four since on receipt of fifth clock pulse the counters are reset. The capacity of the circuit can be easily extended to handle up to nine persons by removing the connection of pin 1 from reset pin (15) and utilising Q1 to Q9 outputs of CD4017 counters. Additional inverters, AND gates and diodes will, however, be required.

Download Full Circuit: Click Here

ELECTRONICS PROJECTS

AUTOMATIC HEAT DETECTOR

This circuit uses a complementary pair comprising NPN metallic transistor T1 (BC109) and pnp germanium transistor T2 (AC188) to detect heat (due to outbreak of fire, etc) in the vicinity and energise a siren. The collector of transistor T1 is connected to the base of transistor T2, while the collector of transistor T2 is connected to relay RL1. The second part of the circuit comprises popular IC UM3561 (a siren and machine-gun sound generator IC), which can produce the sound of a fire-brigade siren. Pin numbers 5 and 6 of the IC are connected to the +3V supply when the relay is in energised state, whereas pin 2 is grounded. A resistor (R2) connected across pins 7 and 8 is used to fix the frequency of the inbuilt oscillator. The output is available from pin 3. Two transistors BC147 (T3) and BEL187 (T4) are connected in Darlington configuration to amplify the sound from UM3561. Resistor R4 in series with a 3V zener is used to provide the 3V supply to UM3561 when the relay is in energised state. LED1, connected in series with 68-ohm resistor R1 across resistor R4, glows when the siren is on. To test the working of the circuit, bring a burning matchstick close to transistor T1 (BC109), which causes the resistance of its emitter-collector junction to go low due to a rise in temperature and it starts conducting. Simultaneously, transistor T2 also conducts because

its base is connected to the collector of transistor T1. As a result, relay RL1 energises and switches on the siren circuit to produce loud sound of a fire brigade siren. Lab note. We have added a table to enable readers to obtain all possible sound effects by returning pins 1 and 2 as suggested in the table.

Download Full Circuit: Click Here

BY: SUKANT KUMAR BEHARA

ELECTRONICS FOR YOU

AUTOMATIC EMERGENCY LIGHT

BY: PRIYANK MUDGAL

This emergency light has the following two advantages:

1. It turns on automatically when the mains power fails, so you need not search it in the dark.

2. Its battery starts charging as soon as the mains resumes.

Operation of the circuit is quite straightforward. Mains supply is stepped down by transformer X1, rectified by a full-wave rectifier comprising diodes D1 and D2, filtered by capacitor C1 and fed to relay coil RL1. The relay energises to connect the battery to the charging circuit through its normally-opened (N/O) contacts. Freewheeling diode D3 acts as a spike buster for the relay.

The charging circuit is built around npn transistor BD139 (T1). The transformer output is fed to the collector of transistor T1, which provides a fixed bias voltage of 6.8V to charge the battery. When the battery is fully charged, the battery voltage becomes equal to the breakdown voltage of the zener diode (ZD1). Zener diode ZD1 conducts to provide an alternative path for the current to ground and battery charging stops.

When mains fails, relay RL1 de-energises. The battery now gets connected to the white LED array comprising LED1 through LED6) through current-limiting resistor R2. The LEDs glow to light up the room. To increase the brightness in your room, you can increase the number of white LEDs after reducing the value of resistor R2 and also use a reflector assembly.

Download Full Circuit: Click Here

ELECTRONICS FOR YOU

PC POWER MANAGER

T.K. Hareendran

Very often we forget to switch off the connected peripherals like monitor, scanner and printer while switching off our PC. This leads to needless energy consumption and possible shortening of the life of the peripheral. PCs with an ATX switch-mode power supply (SMPS) unit are not provided with a mains switch outlet. It is therefore not possible to achieve automatic switching (on/off) of peripheral units with the computer power switch. Here is a simple circuit that turns the connected peripherals on/off along with your PC. It consists of a regulated power supply, a simple USB interface and two electromagnetic relays used as power switches.
The power supply for the circuit is derived from the AC mains via transformer X1. The 15V AC available at
the secondary winding of transformer X1 is first rectified by a bridge recti-fier comprising diodes D1 through D4, smoothed by capacitors C1 and C2, and regulated by IC LM7812 (IC1). The regulated 12V DC is used to energise relay RL1. LED1 works as a power- ‘active’ indicator. To set up the circuit, first connect
the input socket (SOC1) of the circuit to a proper AC mains wall outlet using a three-core power cable. Now connect one end of a standard USB cable to the B-type USB input socket and the other end of the cable to any vacant USB port (A-type) of the PC. Finally, plug one standard four-way switchboard (extension cord) into the supply output socket (SOC2) of the circuit and take power from this switchboard to activate all loads like monitor, scanner, printer and even your PC.

Download Full Circuit: Click Here

electronics for you

IR MUSIC TRANSMITTER AND RECEIVER

PRADEEP G.

Using this circuit, audio musical notes can be generated and heard up to a distance of 10 metres. The circuit can be divided into two parts: IR music transmitter and receiver. The IR music transmitter works off a 9V battery, while the IR music receiver works off regulated 9V to 12V. Fig. shows the circuit of the IR music transmitter. It uses popular melody generator IC UM66 (IC1) that can continuously generate musical tones. The output of IC1 is fed to the IR driver stage (built across the transistors T1 and T2) to get the maximum range. Here the red LED (LED1) flickers according to the musical tones generated by UM66 IC, indicating modulation. IR LED2 and LED3 are infrared transmitting LEDs. For maximum sound transmission these should be oriented towards IR phototransistor L14F1 (T3). The IR music receiver uses popular op-amp IC μA741 and audio-frequency amplifier IC LM386 along with phototransistor L14F1 and some discrete components (Fig. 2). The melody generated by IC UM66 is transmitted through IR LEDs, received by phototransistor T3 and fed to pin 2 of IC μA741 (IC2). Its gain can be varied using potmeter VR1. The output of IC μA741 is fed to IC LM386 (IC3) via capacitor C5 and potmeter VR2. The melody produced is heard through the receiver’s loudspeaker. Potmeter VR2 is used to control the volume of loudspeaker LS1 (8-ohm, 1W). Switching off the power supply stops melody generation.

Download Full Circuit: Click Here

Battery level indicator

Aniruddh K.S.

Normally, in mobile phones, the battery level is shown in dot or bar form. This lets you easily recognise the battery level. Here we present a circuit that lets you know the battery level of a device from the number of LEDs that are glowing. It uses ten LEDs in all. So if three LEDs glow, it indicates battery capacity of 30 per cent. Unlike in mobile phones where the battery-level indicator function is integrated with other functions, here only one comparator IC (LM3914) does it all. The LM3914 uses ten comparators, which are internally assembled in the voltage divider network based on the current-division rule. So it divides the battery level into ten parts. The circuit derives the power supply for its operation from the battery of the device itself. It uses ten LEDs wired in a 10-dot mode. The use of different coloured LEDs makes it easier to recognise the voltage level on the basis of the calibration made. Red LEDs (LED1 through LED3) indicate battery capacity of less than 40 per cent. Orange LEDs (LED4 through LED6) indicate battery capacity of 40 to less than 70 per cent and green LEDs (LED7 through LED10) indicate battery capacity of 70 to under 100 per cent. The brightness of the LEDs can be adjusted by varying the value of preset VR2 between pins 6 and 7. Diode D1 prevents the circuit from reverse-polarity battery connection. The tenth LED glows only when the battery capacity is full, i.e., the battery is fully charged. When the battery is fully charged, relay-driver transistor T1 conducts to energise relay RL1. This stops the charging through normally-open (N/O) contacts of relay RL1.

For calibration, connect 15V variable, regulated power supply and initially set it at 3V. Slowly adjust VR1 until LED1 glows. Now, increase the input voltage to 15V in steps of 1.2V until the corresponding LED (LED2 through LED10) lights up. Now the circuit is ready to show any voltage value with respect to the maximum voltage. As the number of LEDs is ten, we can easily consider one LED for 10 per cent of the maximum voltage. Connect the voltage from any battery to be tested at the input probes of the circuit. By examining the number of LEDs glowing you can easily know the status of the battery. Suppose five LEDs are glowing. In this case, the battery capacity is 50 to 59 per cent of its maximum value. Assemble the circuit on a general purpose PCB. Calibrate it and then enclose in a box.

Download Full Circuit: Click Here

MEDIUM-POWER FM TRANSMITTER

The range of this FM transmitter is around 100 metres at 9V DC supply. The circuit comprises three stages.

The first stage is a microphone preamplifier built around BC548 transistor. The next stage is a VHF oscillator wired around another BC548. (BC series transistors are generally used in low-frequency stages. But these also work fine in RF stages as oscillator.) The third stage is a class-A tuned amplifier that boosts signals from the oscillator. Use of the additional RF amplifier increases the range of the transmitter. Coil L1 comprises four turns of 20SWG enamelled copper wire wound to 1.5cm length of a 4mm dia. air core. Coil L2 comprises six turns of 20SWG enamelled copper wire wound on a 4mm dia. air core. Use a 75cm long wire as the antenna. For the maximum range, use a sensitive receiver. VC1 is a frequency-adjusting trimpot. VC2

should be adjusted for the maximum range. The transmitter unit is powered by a 9V PP3 battery. It can be

combined with a readily available FM receiver kit to make a walkie-talkie set as shown in Fig.

Download Full Circuit: Click Here

CLOCK TIMER

With this simple clock controlled timer, you will never again miss your favourite TV or radio programme. The
TV or radio will switch on automatically at the time preset by you and will remain ‘on’ until the power supply
fails or is disconnected. The circuit uses the AC signals generated at the buzzer terminals of an alarm clock. The AC signals are amplified by transistors T1 and T2 and the amplified output from the emitter of T2 is fed to the inverting input of negative-voltage comparator IC LM311 (IC1). The non-inverting input of IC1
gets a presettable voltage through preset VR1. The inverting and non-inverting inputs of LM311 are different from other op-amps and it outputs sink current through pin 7 or source current through pin 1. When pin 3 of IC1 is at a higher voltage than pin 2, its output sinks as indicated by LED1. This gives a short negative pulse to the monostable wired around timer NE555. Resistor R5 keeps trigger pin 2 of IC2 high. The short-interval monostable outputs a high signal for a brief period to the gate of SCR1 (BT169) and relay RL1
energises. The latching action of SCR1 keeps the relay pulled even when the output of the monostable turns low. The relay can be de-energised by disconnecting the supply to the circuit via switch S1.
The circuit works off a 9V battery. Assemble it on a general-purpose PCB and enclose in a suitable cabinet. Provide an AC outlet in the cabinet to switch on the appliance using the circuit. As mentioned earlier, the input signal is obtained from the buzzer terminals of the clock. Remove the small buzzer of the clock and connect point ‘A’ to the positive terminal and point ‘B’ to the negative terminal of the buzzer. Connect the
mains AC terminal outlet to the normally- opened (N/O) contact of relay RL1. So when the relay energises,
230V AC operates the connected appliance. Set the desired time in the clock by adjusting the alarm set-up and switch on the circuit. When the set time reaches, the appliance will switch on automatically. The circuit can also be connected to digital clocks.

Download Full Circuit: Click Here

By: D. MOHAN KUMAR
ELECTRONICS FOR YOU

Auto Reset Over/Under Voltage Cut-Out

This over/under voltage cut-out will save your costly electrical and electronic appliances from the adverse effects of very high and very low mains voltages. The circuit features auto reset and utilises easily available components. It makes use of the comparators available inside 555 timer ICs. Supply is tapped from different points of the power supply circuit for relay and control circuit operation to achieve reliability.

The circuit utilises comparator 2 for control while comparator 1 output (connected to reset pin R) is kept low

by shorting pins 5 and 6 of 555 IC. The positive input pin of comparator 2 is at 1/3rd of Vcc voltage. Thus as long as negative input pin 2 is less positive than 1/3 Vcc, comparator 2 output is high and the internal flip-flop is set, i.e. its Q output (pin 3) is high. At the same time pin 7 is in high impedance state and LED connected to pin 7 is therefore off. The output (at pin 3) reverses (goes low) when pin 2 is taken more positive than 1/3 Vcc. At the same time pin 7 goes low (as Q output of internal flip-flop is high) and the ED connected to pin 7 is lit. Both timers (IC1 and IC2) are configured to function in the same fashion. Preset VR1 is adjusted for under voltage (say 160 volts) cut-out by observing that LED1 just lights up when mains voltage is slightly greater than 160V AC. At this setting the output at pin 3 of IC1 is low and transistor T1 is in cut-off state. As a result RESET pin 4 of IC2 is held high since it is connected to Vcc via 100 kilo-ohm resistor R4. Preset VR2 is adjusted for over voltage (say 270V AC) cut-out by observing that LED2 just extinguishes when the mains voltage is slightly less than 270V AC. With RESET pin 4 of IC2 high, the output pin 3 is also high. 

As a result transistor T2 conducts and energises relay RL1, connecting load to power supply via its N/O contacts. This is the situation as long as mains voltage is greater than 160V AC but less than 270V AC. When mains voltage goes beyond 270V AC, it causes output pin 3 of IC2 to go low and cut-off transistor T2 and de-energise relay RL1, in spite of RESET pin 4 still being high. 

When mains voltage goes below 160V AC, IC1’s pin 3 goes high and LED1 is extinguished. The high output at pin 3 results in conduction of transistor T1. As a result collector of transistor T1 as also RESET pin 4 of IC2 are pulled low. 

Thus output of IC2 goes low and transistor T2 does not conduct. As a result relay RL1 is de-energised, which causes load to be disconnected from the supply. When mains voltage again goes beyond 160V AC (but less than 270V AC) the relay again energises to connect the load to power supply.

DownLoad Full Circuit: Click Here

by: J. Gopalakrishnan

Infrared Cordless Headphone

Using this low-cost project one can reproduce audio from TV without disturbing others. It does not use any wire connection between TV and headphones. In place of a pair of wires, it uses invisible infrared light to transmit audio signals from TV to headphones. Without using any lens, a range of up to 6 metres is possible. Range can be extended by using lenses and reflectors with IR sensors comprising transmitters and receivers.
IR transmitter uses two-stage transistor amplifier to drive two series-connected IR LEDs. An audio output
transformer is used (in reverse) to couple audio output from TV to the IR transmitter. Transistors T1 and T2
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 9-volt mains adapter or battery. Red LED1 in transmitter circuit functions as a zener diode (0.65V) as well as supply-on indicator. IR receiver uses 3-stage transistor amplifier. The first two transistors (T4 and T5) form audio signal amplifier while the third transistor T6 is used to drive a headphone. Adjust potmeter VR2 for max. clarity. Direct phototransistor towards IR LEDs of transmitter for max. range. A 9-volt battery can be used with receiver for portable operation.

Dual-Channel Digital Volume Control

This circuit could be used for replacing your manual volume control in a stereo amplifier. In this circuit, push-to-on switch S1 controls the forward (volume increase) operation of both channels while a similar switch
S2 controls reverse (volume decrease) operation of both channels. Here IC1 timer 555 is configured as
an astable flip-flop to provide low-frequency pulses to up/down clock input pins of presetable up/down counter 74LS193 (IC2) via push-to-on switches S1 and S2. To vary the pulse width of pulses from IC1, one may replace timing resistor R1 with a variable resistor. Operation of switch S1 (up) causes the binary output to increment while operation of S2 (down) causes the binary output to decrement. The maximum
count being 15 (all outputs logic 1) and minimum count being 0 (all outputs logic 0), it results in maximum and
minimum volume respectively. The active high outputs A, B, C and D of the counter are used for controlling
two quad bi-polar analogue switches in each of the two CD4066 ICs (IC3 and IC4). Each of the output bits, when high, short a part of the resistor network comprising series resistors R6 through R9 for one channel and R10 through R13 for the other channel, and thereby control the output of the audio signals being fed to the inputs of stereo amplifier. Push-to-on switch S3 is used for resetting the output of counter to 0000, and thereby turning the volume of both channels to the minimum level.

Download Full Circuit: Click Here

BY SHEENA K.

Audio-Visual Extra Ringer for Phone

Many a times one needs an extra telephone ringer in an adjoining room to know if there is an incoming call. For example, if the telephone is installed in the drawing room you may need an extra ringer in the bedroom. All that needs to be done is to connect the given circuit in parallel with the existing telephone lines using twin
flexible wires. This circuit does not require any external power source for its operation. The section comprising resistor R1 and diodes D5 and LED1 provides a visual indication of the ring. Remaining part of the circuit is the audio ringer based on IC1 (BA8204 or ML8204). This integrated circuit, specially designed for telecom application as bell sound generator, requires very few external parts.
It is readily available in 8-pin mini DIP pack. Resistor R3 is used for bell sensitivity adjustment. The bell frequency is controlled by resistor R5 and capacitor C4, and the repetition rate is controlled by resistor R4 and capacitor C3.

Download Full Circuit: Click Here

LOW BUDGET INTERCOM

THE central component in this Intercom project is an integrated circuit designed for audio amplification, type LM386. It is shown as IC1 in Fig.4.3. The circuit shows that it needs few additional components to do its job of amplifying audio signals. The internal voltage gain is set at 200 by capacitor C2, connected between
pins 1 and 8. Two low-power loudspeakers, LS1 and LS2, act as microphone or speaker depending on the position of the double-pole, double-throw reversing switch, S2.

Download Full Circuit: Click Here

Everyday Practical Electronics, January 2009

PHONE/FAX MISSED CALL ALERT

Constructional Project This device detects an incoming call on your phone or fax and lights an LED and latches on a relay, which you can use to switch on a lamp or horn in another room or your garage.

So what’s wrong with listening for the phone ringer or looking at the fax machine’s ‘out’ tray? If you work

at home you need to be able to respond to phone calls or faxes as soon as they come in, but you cannot be hovering over the phone all day; there are times when you have to leave your office or home and if you do not physically lift the phone handset and listen (if you have BT Answer 1571) or check the fax as soon as you arrive back, calls or faxes could be without a response for some time. 

Or maybe you have an office but spend some time in the workshop. Same problem – or even more so if you are waiting on an important call or fax. So this is the remedy. Build this device and it will let you know that a phone call has been made or a fax has been received, without you needing to actually check the phone or fax.

What’s more, you can use it with a remote light or siren to alert you over the noise of machinery!

The Phone/Fax Missed Call Alert hooks up easily to the fax machine’s phone line. It connects in very easily, using a standard low-cost modular cable. The kit of parts should set you back no more than about £15 and you should be able to build it up in a couple of hours at most.

How it works

When someone dials your phone or fax number, the exchange sends out short (200ms) bursts of a 75V 17Hz AC signal – the ‘ring signal’. It’s this signal that causes your phone to ring or triggers the fax machine into answering and receiving the message. Our Missed Call Alert is designed to monitor the phone line and respond to the same ring signal, using it to trigger a flipflop and hence latch a relay.

Download Full Circuit: Click Here

By JIM ROWE
Everyday Practical Electronics, January 2008

ANTI-THEFT SECURITY FOR CAR AUDIOS

This small circuit, based on popular CMOS NAND chip CD4093, can be effectively used for protecting
your expensive car audio system against theft.

Download Full Circuit: Click Here

Add on stereo channel selector

The add-on circuit presented here is useful for stereo systems. This circuit has provision for connecting stereo outputs from four different sources/channels as inputs and only one of them is selected/ connected to the output at any one time.

Download Full Circuit: Click Here