Intelligent Electronic Lock

This intelligent electronic lock circuit is built using transistors only. To open this electronic lock, one has to press tactile switches S1 through S4 sequentially. For deception you may annotate these switches with different numbers on the control panel/keypad. For example, if you want to use ten switches on the keypad marked ‘0’ through ‘9’, use any four arbitrary numbers out of these for switches S1 through S4, and the remaining six numbers may be annotated on the leftover six switches, which may be wired in parallel to disable switch S6 (shown in the figure). When four password digits in ‘0’ through ‘9’ are mixed with the remaining six digits connected across disable switch terminals, energisation of relay RL1 by unauthorised person is prevented.

For authorised persons, a 4-digit password number is easy to remember. To energise relay RL1, one has to press switches S1 through S4 sequentially within six seconds, making sure that each of the switch is kept depressed for a duration of 0.75 second to 1.25 seconds. The relay will not operate if ‘on’ time duration of each tactile switch (S1 through S4) is less than 0.75 second or more than 1.25 seconds. This would amount to rejection of the code. A special feature of this circuit is that pressing of any switch wired across disable switch (S6) will lead to disabling of the whole electronic lock circuit for about one minute.

Even if one enters the correct 4-digit password number within one minute after a ‘disable’ operation, relay RL1 won’t get energised. So if any unauthorised person keeps trying different permutations of numbers in quick successions for energisation of relay RL1, he is not likely to succeed. To that extent, this electronic lock circuit is fool-proof. This electronic lock circuit comprises disabling, sequential switching, and relay latch-up sections. The disabling section comprises zener diode ZD5 and transistors T1 and T2. Its function is to cut off positive supply to sequential switching and relay latch-up sections for one minute when disable switch S6 (or any other switch shunted across its terminal) is momentarily pressed.

During idle state, capacitor C1 is in discharged condition and the voltage across it is less than 4.7 volts. Thus zener diode ZD5 and transistor T1 are in non-conduction state. As a result, the collector voltage of transistor T1 is sufficiently high to forward bias transistor T2. Consequently, +12V is extended to sequential switching and relay latch-up sections. When disable switch is momentarily depressed, capacitor C1 charges up through resistor R1 and the voltage available across C1 becomes greater than 4.7 volts. Thus zener diode ZD5 and transistor T1 start conducting and the collector voltage of transistor T1 is pulled low. As a result, transistor T2 stops conducting and thus cuts off positive supply voltage to sequential switching and relay latch-up sections.

Thereafter, capacitor C1 starts discharging slowly through zener diode D1 and transistor T1. It takes approximately one minute to discharge to a sufficiently low level to cut-off transistor T1, and switch on transistor T2, for resuming supply to sequential switching and relay latch-up sections; and until then the circuit does not accept any code. The sequential switching section comprises transistors T3 through T5, zener diodes ZD1 through ZD3, tactile switches S1 through S4, and timing capacitors C2 through C4. In this three-stage electronic switch, the three transistors are connected in series to extend positive voltage available at the emitter of transistor T2 to the relay latch-up circuit for energising relay RL1.

When tactile switches S1 through S3 are activated, timing capacitors C2, C3, and C4 are charged through resistors R3, R5, and R7, respectively. Timing capacitor C2 is discharged through resistor R4, zener diode ZD1, and transistor T3; timing capacitor C3 through resistor R6, zener diode ZD2, and transistor T4; and timing capacitor C4 through zener diode ZD3 and transistor T5 only. The individual timing capacitors are chosen in such a way that the time taken to discharge capacitor C2 below 4.7 volts is 6 seconds, 3 seconds for C3, and 1.5 seconds for C4. Thus while activating tactile switches S1 through S3 sequentially, transistor T3 will be in conduction for 6 seconds, transistor T4 for 3 seconds, and transistor T5 for 1.5 seconds.

The positive voltage from the emitter of transistor T2 is extended to tactile switch S4 only for 1.5 seconds. Thus one has to activate S4 tactile switch within 1.5 seconds to energise relay RL1. The minimum time required to keep switch S4 depressed is around 1 second. For sequential switching transistors T3 through T5, the minimum time for which the corresponding switches (S1 through S3) are to be kept depressed is 0.75 seconds to 1.25 seconds. If one operates these switches for less than 0.75 seconds, timing capacitors C2 through C4 may not get charged sufficiently. As a consequence, these capacitors will discharge earlier and any one of transistors T3 through T5 may fail to conduct before activating tactile switch S4.

Thus sequential switching of the three transistors will not be achieved and hence it will not be possible to energise relay RL1 in such a situation. A similar situation arises if one keeps each of the mentioned tactile switches de-pressed for more than 1.5 seconds. When the total time taken to activate switches S1 through S4 is greater than six seconds, transistor T3 stops conducting due to time lapse. Sequential switching is thus not achieved and it is not possible to energise relay RL1. The latch-up relay circuit is built around transistors T6 through T8, zener diode ZD4, and capacitor C5. In idle state, with relay RL1 in de-energised condition, capacitor C5 is in discharged condition and zener diode ZD4 and transistors T7, T8, and T6 in non-conduction state.

However, on correct operation of sequential switches S1 through S4, capacitor C5 is charged through resistor R9 and the voltage across it rises above 4.7 volts. Now zener diode ZD4 as well as transistors T7, T8, and T6 start conducting and relay RL1 is energised. Due to conduction of transistor T6, capacitor C5 remains in charged condition and the relay is in continuously energised condition. Now if you activate reset switch S5 momentarily, capacitor C5 is immediately discharged through resistor R8 and the voltage across it falls below 4.7 volts. Thus zener diode ZD4 and transistors T7, T8, and T6 stop conducting again and relay RL1 de-energises. 

Sourced by : Extreamcircuits

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EE ternal Blinker

You on occasion see promoting signs in stores with a blinking LED that seems to blink without end while working from a sin-gle battery cell. That’s naturally an irresistible problem for a real digitals hobbyist. And here’s the circuit. It consists of an astable multivibrator with special proper-ties. A a hundred-µF electrolytic capacitor is charged comparatively slowly at a low present after which discharged by approach of the LED with a short pulse. The circuit also provides the essential voltage boosting, for the cause that 1.5 V is without a doubt too low for an LED. 

Circuit diagram :

EE-ternal Blinker Circuit Diagram

The two oscillograms show how the circuit works. The voltage on the collector of the PNP transistor jumps to roughly 1.5 V after the electrolytic capacitor has been discharged to close to zero.3V at this point by implys of a 10-kΩ resistor. It is charged to approximately 1.2 V on the other facet. The difference voltage across the electrolytic capacitor is subsequently zero.9 V when the blink pulse seems. This voltage adds to the battery voltage of 1.5 V to enable the amplitude of the coronary heart beat on the LED to be as excessive as 2.4 V. However, the voltage is in fact limited to roughly 1.8 V via the LED, as proven through the 2nd oscillogram. The voltage across the LED mechanically fits the voltage of the LED that's used. It can theoretically be as excessive as three V. 

The circuit has been optimised for low-power operation. That is why the true flip-flop is built the use of an NPN transistor and a PNP transistor, which keep away froms losing keep watch over present. The two transistors only habits all through the brief interval when the LED blinks. To make positive that steady working prerequisites and reliable oscillation, an extra stage with negative DC remarks is integrated. Here again, particularly high resistance worths are used to minimise current consumption. 

The present consumption will also be estimated in response to the charging current of the electrolytic capacitor. The average voltage throughout the 2 10-kΩ charging resistors is 1 V in whole. That implies that the aver-age charging current is 50 µA. Exactly the comparable quantity of charge is additionally drawn from the battery all through the LED pulse. The reasonable present is consequently round 100 µA. If we suppose a battery capacity of 2500 mAh, the battery will have to ultimate for round 25,000 hours. That is greater than two yrs, which is almost an eternity. As the current lowers somewhat as the bat-ter voltage drops, inflicting the LED to blink less brightly, the true useful existence may be even longer. That makes it greater than (almost) eternal.

Author : Burkhard Kainka

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Build 10 Watt Audio Power Amplifier Circuit

10W Audio Power Amplifier Circuit

10W PA.The 10 watts power amplifier circuit with the aid of transistor describe right here is an audio amplifier with output power of 10W.Used as a low frequency type AB Amplifier. Transistor has high output present and very low distortion.This 10W audio amplifier circuit diagram using Transistor is good for small room or car audio device.This circuit is a general-purpose 10W audio amplifier for moderate-power PA or modulator use in an AM transmitter.

With better voltages and a change in bias resistors,up to 30 W may additionally be obtained.

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LED Matrix Horizontally

LEDs provide a befitting way to electronically display information. whereas the seven-segment LED brandish, organized in the pattern of the digit 8, is common, it does not permit the brandish of some alphanumeric individual features. A 5×7 commanded matrix permits the display of all ASCII individual features, as well as graphics shapes.

The circuit in this conceive concept displays an unconventional way to use a 5×7 LED matrix.You can use a conceive encompassing a set of 5×7 commanded flats without altering any thing in the circuitry, except for the arrangement of the commanded units. 

 Using one 5×7 LED matrix, or N units, horizontally instead of vertically allows the display of two characters, or 2×N characters. The minimum pattern for lowercase and uppercase letters requires only a 3×5 LED configuration, except for the letters M and m, which require at least a 5×5 LED configuration and need a dedicated subroutine.

The circuit in Figure 1 uses an 8-bit, 18-pin PIC micro controller and a decade counter to drive one or two 5×7 LED units to provide a display module of two or four digits. The circuit uses a small pushbutton switch to increment the counter. By default, the circuit works in high-brightness mode. If you press the pushbutton during power-on, the circuit works in low-power mode.

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60W POWER AMPLIFIER CLASS B CIRCUIT DIAGRAM

60W POWER AMPLIFIER CLASS B CIRCUIT DIAGRAM

Capacitor C1 regulates the low frequencies (bass), as the capacitance grows, the low frequencies are getting louder. Capacitor C2 regulates the higher frequencies (treble), as the capacitance grows, the higher frequencies are getting quieter.

This is a class B amplifier, this means, that a current must flow through the end transistors, even if there is no signal on the input. This current can be regulated with the 500 Ohm trimmer resistor. As this current increases, the sound of the amplifier is better, but output transistors are dispatching more heat. If the current is decreased, the transistors are dispatching less heat, but the sound quality is decreased.

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Simple Stereo VU Meter

I like to peer gentles transfer to music. This venture will point out the volume level of the audio going to your audio system with the help of lighting fixtures up LEDS. The LEDS will additionally be any shade so combine them up and in point of fact make it seem to be good. The input of the circuit is connected to the speaker output of your audio amplifier. You wish to construct two equivalent units to point out each proper and left channels. The input signal degree is adjusted by using the 10k ohm VR. If you wish to make an extraordinarily huge scale edition of this unit and dangle it on your wall there's an not obligatory output transistor that can power many LEDS immediately. The unit I built drove three LEDS for every output. The sequence of the LEDS lighting are as follows Pin 1, 18, 17, sixteen, 15, 14, 13, 12, eleven, 10.

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Component placement design

Here I will share about the arrangement of components in the box. That where the components are a series of audio amplifiers that use relatively large components, which consume a lot of places in the box to the amplifier.





But in this post I just gave inspiration only in the arrangement, or design place for neat, clean and have good audio output as well. please see image below.

Description

1.AC 220V terminal

2.Switch on/off

3.Transformer

4.Diode

5.Capacitor elco

6.PCB kit amplifier

7.Heatsink

8.Master Volume

9.Terminal input output.

Then this is the image of the booster amplifier using 2 sets of Sanken 2SC2922 and 2SA1216 transistors, which has a high output power.

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Transmitter and Receiver Infra Red Headphone

Transmitter and receiver circuit using infra red audio signal is applied to emit an audio signal and will received on a headphones. Making his series is not too difficult, the transmitter and receiver circuit scheme can be seen below.

Transmiter schematics

Receiver schematics

After the series finished, you can try to give the audio inputs on the transmitter and point the LED transmitter to the receiver. Maximum distance is a few meters may not be more than 10 meters, but you can listen to music without wires while using infra red.

image[link]

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VFD Talking Alarm Clock

Are you having a bothersome time waking your hubby from sleeping? And when you go away the house for work, are you unsure that he has not gotten out of bed? One thing with the intention to cease your issues is to use this clock that does not simply tell time but in addition “swears”.

This is an All-in-one alarm clock. It shows an alphanumeric character, it has a calendar, temperature, and a gentle sensor to keep watch over its brightness. You can plug it on to your energy supply or use a battery. Although that is cool, It’s now not adequate being round kids. We don’t want young youngsters to examine to swear or say dangerous things, right?

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1992 Regal Buick Wiring Diagram

1992 Regal Buick Wiring Diagram

The Part of 1992 Regal Buick Wiring Diagram: defrost, dimmer, coolant temp sens, cycling press,
primary cooling, blower, secondary cooling fan, rear defog, heater ctrl assembly, convenience center, select center, clust fuse, electronic ctrl module, throttle sensor, fusible element, solenoid, cluth diode, comp ctrl relay, air temp valve motor

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1996 Ford Windstar Wiring Diagram

1996 Ford Windstar Wiring Diagram

The Part of 1996 Ford Windstar Wiring Diagram: power distribution, common, rear, ignition, fuse panel,  battery, instrument illumination, radio, left rear speaker, remote headphone module, solid state, right rear

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The Differential Input and Differential Output

For getting balanced differential output 
we use this circuit. In this circuit  two source is present, so the
superposition theory is applied to get the output. In this circuit both
the inverting and non-inverting terminal is working.It rejects the
common-mode voltages, so  it is very useful in noisy environments.

A  differential input and differential output amplifier using two identical Op amp. It is     most commonly used as a preamplifier and driving push-pull  arrangement. The differential input and output  are inphase or the same polarity provided  V_in  =V_x – V_y and

V_o  =V_ox – V_oy

When we want to find out the 1^st op-amps output V_OX , we will use the  superposition theory.

When we get  V_X  is active , V_Y  is  inactive then ,

In non inverting terminal 

V₁= (1+ )V_X

When we get  V_y   is  active,  V_x   is  inactive then,

In  inverting terminal,

V₁ = - V_y

 So, V_ox = V₁+V₁

                =(1+ )V_X  -  V_y

 

Fig: The circuit diagram of the differential input and output amplifier. 

When we want to find out the 2^nd  op-amps output V_Oy ,we will use superposition theory.

                      When we get  V_X  is active , V_Y  is  inactive then

                      In  inverting terminal ,

                      V₂= - V_x

        

      Again, when  we get  V_y  is  active ,  V_x  is  inactive then

        In non inverting terminal we get, 

V₂= (1+ )V_y

So, V_oy = V₂+V₂

                                      =(1+ )V_y - V_x

So the output result   

V_o = V_ox  –  V_oy 

= (1+ )V_X  -  V_y  –[(1+ )V_y - V_x ]

                                      = (1+ ) ( V_X - V_y ) +( V_X - V_y )

                                       = ( V_X - V_y ) (1+ )

Design

To design a input and differential output amplifier,  taking a  differential output of at least 3.7V and the  differential  input V_in  =10V.

                        We know,

 V_o = ( V_X - V_y ) (1+ )

            Or, 3.7 = (0.1) (1+ )

 Or, 37 = (1+ )

            Or, 36 = 

            Or, R_f  = 18 R₁

                                    Let, R₁ = 100Ώ, then R_f  = 1.8 KΏ . 

                   Fig: The designing circuit diagram of the differential input and output amplifier. 

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1971 Ford Half Ton Wiring Diagram

1971 Ford Half Ton Wiring Diagram

The Part of 1971 Ford Half Ton Wiring Diagram: direct switch, high beam, right headlight, horn relay,
green wire, indicator, fusible link, battery, starter relay, egr system, left marker light, ignition module, distributor, yellow wire, alternator indicator, washer fuse, windshield wiper switch, regulator,

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TDA2004 stereo bridge audio amplifier

Most of the lovers, especially in audio electronics, it will never escape from this one component of the IC TDA2004. Because these components are very easy to get and the price is also quite cheap. Amplfiier audio series was also quite easy to make because the circuit is not too complicated, and one ic also already has 2 outputs and inputs.

Not only that, the audio is processed from the IC is also well qualified, many power power branded car, using it as an amplifier ic. Nothing mistake this ic tried to make an audio amplifier. For the circuit scheme can be seen below.

with this amplifier circuit you can easily enhance your audio levels, from your stereo walkman, Ipod, tuner, MP3 player or MP4, the portable receiver, laptops or PCs

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Power Flip Flop Using A Triac

Modern electronics is indispensable for every large model railroad system, and it provides a solution to almost every problem. Although ready-made products are exorbitantly expensive, clever electronics hobbyists try to use a minimum number of components to achieve optimum results together with low costs. This approach can be demonstrated using the rather unusual semiconductor power flip-flop described here. A flip-flop is a toggling circuit with two stable switching states (bistable multivibrator). It maintains its output state even in the absence of an input pulse.

Flip-flops can easily be implemented using triacs if no DC voltage is available. Triacs are also so inexpensive that they are often used by model railway builders as semiconductor power switches. The decisive advantage of triacs is that they are bi-directional, which means they can be triggered during both the positive and the negative half-cycle by applying an AC voltage to the gate electrode (G). The polarity of the trigger voltage is thus irrelevant. Triggering with a DC current is also possible. Figure 1 shows the circuit diagram of such a power flop-flop. A permanent magnet is fitted to the model train, and when it travels from left to right, the magnet switches the flip-flop on and off via reed switches S1 and S2.

Circuit diagram:

In order for this to work in both directions of travel, another pair of reed switches (S3 and S4) is connected in parallel with S1 and S2. Briefly closing S1 or S3 triggers the triac. The RC network C1/R2, which acts as a phase shifter, maintains the trigger current. The current through R2, C1 and the gate electrode (G) reaches its maximum value when the voltage across the load passes through zero. This causes the triac to be triggered anew for each half-cycle, even though no pulse is present at the gate. It remains triggered until S2 or S4 is closed, which causes it to return to the blocking state.The load can be incandescent lamps in the station area (platform lighting) or a solenoid-operated device, such as a crossing gate. The LED connected across the output (with a rectifier diode) indicates the state of the flip-flop. 

The circuit shown here is designed for use in a model railway system, but there is no reason why it could not be used for other applications. The reed switches can also be replaced by normal pushbutton switches. For the commonly used TIC206D triac, which has a maximum current rating of 4 A, no heat sink is necessary in this application unless a load current exceeding 1 A must be supplied continuously or for an extended period of time. If the switch-on or switch-off pulse proves to be inadequate, the value of electrolytic capacitor C1 must be increased slightly.

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Simple Digital Switching System

This circuit can control any one out of 16 devices with the help of two push-to-on switches. An up/down counter acts as a master-controller for the system. A visual indication in the form of LEDs is also available.  IC1 (74LS193) is a presettable up/ down counter. IC2 and IC3 (74LS154) (1of 16 decoder/demultiplexer) perform different functions, i.e. IC2 is used to indicate the channel number while IC3 switches on the selected channel.

Digital Switching System Circuit Diagram :

Before using the circuit, press switch S1 to reset the circuit. Now the circuit is ready to receive the input clock. By pressing pressing switch S2 once, the counter advances by one count. Thus, each pressing of switch S2 enables the counter to advance by one count. Likewise, by pressing switch S3 the counter counts downwards.

The counter provides BCD output. This BCD output is used as address input for IC2 and IC3 to switch one (desired channel) out of sixteen channels by turning on the appropriate triac and the corresponding LED to indicate the selected channel.  The outputs of IC3 are passed through inverter gates (IC4 through IC6) because IC3 provides negative going pulses while for driving the triacs we need positive-going pulses. The high output of inverter gates turn on the npn transistors to drive the triacs. Diodes connected in series with triac gates serve to provide unidirectional current for the gate-drive.

Sorce : www.ecircuitslab.com/2012/08/digital-switching-system.html

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Your PC Needs Some Illumination

Try to lighten up you PC by using LED flex lights to surround the casing. The result will be much appreciated when the room is dark. The chain is housed in rubber plastic which makes more light to be projected out right angles as if some miracle is happening inside the PC.

You can choose which color to use or what you wish to blend with the design of your room. The LED strips are very flexible and customizable which makes them popular. It is very easy to install these strips by using Velcro strips of adhesive backing. You may also use the LED strips in any part of your room like the hairdresser mirror. Click here to visit the project page.

 

 

 

 

Source by : Streampowers

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Dual High Side Switch Controller

Circuit diagram :

Dual High Side Switch Controller Circuit Diagram

One of the most frequent uses of n-channel MOSFET’s is as a voltage controlled switch. To ensure that the MOSFET delivers the full supply voltage to the load it is necessary for the gate voltage to be a few volts above the supply voltage level. This can be a problem if no other suitable higher volt-age sources are available for use elsewhere in the circuit. The LTC 1982 dual high-side switch controller from Lin-ear Technology (www.linear-tech.com) solves this problem by incorporating a voltage tripler circuit in the gate driver stage. The gate voltage is limited to +7.5 V which is 2.0 V above the IC’s maximum operating voltage. It can directly drive the gate of logic-level MOSFET with a VGS(th) from 1.0 V to 2.0 V. A suitable n-channel logic level MOSFET would be the BSP 295. This device can switch up to 1.5 A and is available in an SOT 233 SMD package.

http://streampowers.blogspot.com/2012/06/dual-high-side-switch-controller.html 

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10W audio power amplifier with bass boost

As the amplifier circuit also uses a number of frequencies to drive the loudspeaker, the bass frequencies will be reduced. Therefore need to be plugged the bass-boost control at fedback loop amplifier, this is done to overcome the decline in quality.


Graph bass can reach a maximum at +16.4 dB @ 50Hz.

This circuit can be connected directly to the CD player, tuner, and tape recorders. Q3 and Q4 must be in pairs with a heatsink.

Adjust the volume control at minimum position and R3 with a minimum value of resistance as well. try enabling circuit R3 da set up to read the flow of about 20 to 25mA. Wait for 15 minutes, connect the ground at J1, P1, C2, C4 C3dan. Connect also C9 at the output ground.

For his series of power supply you can use the following scheme that fits perfectly with this amplifier.

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Voltage Regulator Calculation

Before you can design an adjustable voltage regulator into your circuit, or do a redesign, you need to calculate the values for two resistors. This is not difficult in itself, but actually finding the right resistors may pose problems. Fortunately a trick is available to make it all much easier. With most adjustable voltage regulators like the LM317 and LM337, the input voltage has to be 1.2 to 1.25 volts above the desired output voltage. This is because the voltage at the ADJ (adjust) input is internally compared to a reference voltage with that value. The reference voltage always exists across R1.

Circuit diagram:

Voltage Regulator Calculation Circuit Diagram

Together with preset R2 it determines the current flowing through the ADJ pin, as follows: Vout = VREF [1+(R2/R1)]+I ADJ R2 If for the sake of convenience we ignore I ADJ, enter the reference voltage (1.2 V) and for R1 select a value of one thousand times that voltage (i.e., 1.2 k?) then the equation is simplified to: R2 = 1000 (Vout – 1.2) In practice, simply determine the voltage drop across R2 (output voltage minus reference voltage) and you get your resistance value directly in kilo-ohms. For example, for 5 V R2 becomes 5–1.2 = 3.8 k? which is easiest made by connecting 3.3k and 470R resistors in series. In the case of relatively low voltages, smaller resistor values are recommended. This is because sufficient current needs to flow to enable the voltage regulator to do its job. A simple solution is to choose, say, 120 ? for R1. R2 then becomes: R2 = 100 (Vout – 1.2)

Author: Victor Himpe
Copyright: Elektor Electronics

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Electromagnetic Sensor Circuit Using 741 IC

This is a design schematic to sensor the electromagnetic field. This circuit is based or built by 741 IC. This IC is an op-amp. The circuit can detect the field even hidden wrings. This is the figure of the schematic.


A 1mH inductor is used for sensing the electric field. The electric field will induce a small voltage in the sensor inductor and this induced voltage is amplified by the op amp. The headphone connect at the output of the op amp will give an audio indication of the electric field. For example, the electric field around a main transformer can be heard as a 50 Hz hum. The POT R4 can be used to adjust the gain of the amplifier. By keeping the sensor inductor near to a telephone line, you can even hear the telephone conversations. All electrolytic capacitors must be rated at least 15V. The switch S1 can be a slide type ON/OFF switch. The POT R4 can be used to adjust the gain. It is better to have a radial type inductor for L1.

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Usb Power Socket Circuit Diagram

Today, almost all computers contain logic blocks for implementing a USB port. A USB port, in practice, is capable of delivering more than 100 mA of continuous current at 5V to the peripherals that are connected to the bus. So a USB port can be used, without any trouble, for powering 5V DC operated tiny electronic gadgets. Nowadays, many handheld devices (for instance, portable reading lamps) utilise this facility of the USB port to recharge their built-in battery pack with the help of an internal circuitry.Usually 5V DC, 100mA current is required to satisfy the input power demand. Fig. 1 shows the circuit of a versatile USB power socket that safely converts the 12V battery voltage into stable 5V.

Circuit diagram:

Fig. 1: Circuit of USB power socket

This circuit makes it possible to power/recharge any USB power-operated device, using in-dash board cigar lighter socket of your car. The DC supply available from the cigar lighter socket is fed to an adjustable, three-pin regulator LM317L (IC1). Capacitor C1 buffers any disorder in the input supply.Resistors R1 and R2 regulate the output of IC1 to steady 5V, which is available at the ‘A’ type female USB socket.

Red LED1 indicates the output status and zener diode ZD1 acts as a protector against high voltage. Assemble the circuit on a general-purpose PCB and enclose in a slim plastic cabinet along with the indicator and USB socket. While wiring the USB outlet, ensure correct polarity of the supply. For interconnection between the cigar plug pin and the device, use a long coil cord as shown in Fig. 2. Pin configuration of LM317L is shown in Fig. 3.

Author : T.K. Hareendran - Source : EFY Mag

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Dual Input Far Field Noise Suppression Microphone Amplifier Circuit

This is a circuit diagram for microphone amplifier. This circuit is using LMV1090 as based op amp signal in the circuit. This is the figure of the circuit;

The LMV1090 is a fully analog dual differential input, differential output, microphone array amplifier designed to reduce background acoustic noise, while delivering superb speech clarity in voice communication applications. The LMV1090 preserves near-field voice signals within 4cm of the microphones while rejecting far-field acoustic noise greater than 50cm from the microphones. Up to 20dB of far-field rejection is possible in a properly configured and using ±0.5dB matched microphones. [Schematic circuit source: National Semiconductor Notes].

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5000W High Power Audio Amplifier

The High Power Amplifier has great advantages are 5000W ultra-light, high-power audio amplifier, without switching-mode power supply. This ambit is of an 2 x 2,500W RMS Stereo amplifier, super-light and after switching-mode ability supply. The ambit aloof shows a channel, and the ability accumulation that it assists to the two channels. The audio ambit should be duplicated, but the ability accumulation assists to the two channels after problems.

Click To view larger | 5000W High Power Amplifier Audio Circuits Diagrams

A adapted affliction should be destined to the careful agent of the audio line, that should be of audio-high-quality, of the blazon acclimated in microphone pre amps ascribe line. The accomplished accumulation (2 channels) of 5,000W RMS it should not counterbalance added than 32 lbs, already central of an adapted brownish box.

WARNING:

This ambit is alone for abecedarian use. It contains not-isolated genitalia of the electric AC net and it can be actual dangerous. The access for the speakers are not abandoned of the calm AC net and it requests added care. This action seeks to acting a accepted ability accumulation with abundant weight and amount reduction, after necessarily to use a switching-mode ability supply.

This action cannot be accustomed in some countries for commercial-use. The columnist doesn’t accept any albatross for the anatomy as that ambit it will be applied.

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Cheap And Cheerful Transistor Tester

By using a simple visual indicating system, this small transistor tester allows you to run a quick ‘go/non-go’ check on NPN as well as PNP transistors. If the device under test is a working NPN then the green LED (D1) will flash, while the red counterpart will flash for a functional PNP device. However if the transistor is shorted, both LEDs will flash, and an open-circuit device will cause the LEDs to remain off. The circuit is based on just one CD4011B quad NAND gate IC, four passive parts and two LEDs. The fourth gate in the IC is not used and its inputs should be grounded.

Alternatively, you may want to connect its inputs and output in parallel with IC1.C to increase its drive power to the transistor test circuit. IC1.A and IC1.B together with R2, R3 and C1 form an oscillator circuit that generates a low-frequency square wave at pin 4. This signal is applied to the emitter of the transistor under test as well as to inverter IC1.C. The inverted signal from IC1.C and the oscillator output then drive the test circuit (LEDs, device under test, R1) in such a away that the voltage across that part of the circuit is effectively reversed all the time.

For example, with an NPN transistor under test, when pin 10 is High and pin 4, Low, current flows through LED D1 and the forward biased transistor. However, no current will flow when pins 10 and 4 change states, since the transistor is then reverse-biased. The green LED, D1, will therefore flash at the rate determined by the oscillator. As you would expect to happen, a PNP transistor will be forward biased when pin 10 is Low and 4, High, enabling current to flow through the red LED in that case.

A supply rail of around 3 V (two series connected 1.5-V batteries) should be adequate. To prevent damage to the transistor under test, supply voltages higher than 4.5 V should not be used. Because the LED currents are effectively limited to a few mA by the output of IC1.C (also slightly dependent on the supply voltage), it is recommended to use high-efficiency devices for D1 and D2.

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Extension for LiPo Charger

Extension for LiPo Charger Project Image

The ‘Simple LiPo Charger’ published in Elektor Electronics April 2005 is a small and handy circuit that allows you to quickly charge two or three LiPo cells. Especially in the model construction world are LiPo batteries used a lot these days, particularly model aeroplanes. 

It is usual to use a series connection of three cells with these models. Since working with these model aeroplanes usually happens in the field, it would be nice if the batteries could be charged from a car battery.

We therefore designed a voltage converter for the LiPo charger concerned, which makes it possible to charge three cells in series. The voltage per cell increases while charging to a value of about 4.2 V, which gives a total voltage of 12.6 V. The converter, therefore, raises the 12-V voltage from the car battery to 16.5 V, from which the LiPo charger can be powered. 

Extension for LiPo Charger Circuit Diagram

A step-up controller type MAX1771 in combination with an external FET carries out the voltage conversion. The IC operates at a moderately high switching frequency of up to 300 kHz, which means that quite a small coil can be used. 

Because the IC uses pulse frequency modulation (PFM) it combines the advantages of pulse width modulation (high efficiency at high load) with very low internal current consumption (110µA). 

The IC is configured here in the so-called non-bootstrapped mode, which means that it is powered from the input voltage (12 V). The output voltage is adjusted with voltage divider R2/R3. This can be set to any required value, provided that the output voltage is greater than the input voltage. 

Extension for LiPo Charger PCB Layout


Finally, sense resistor R1 determines the maximum output current that the circuit can deliver. With the 25 mΩvalue as indicated, this is 2.5 A. Link

COMPONENTS LIST:
Resistors:
R1 = 25mΩ(e.g., Digikey # 2FR025-ND)
R2 = 100kΩ
R3 = 10kΩ
Capacitors:
C1,C4,C8 = 100nF
C2,C3 = 47µF 25V radial
C5,C7 = 100µF 25V radial
C6 = 100pF
Semiconductors:
D1 = 31DQ05 (e.g., Digikey #31DQ05-ND)
IC1 = MAX1771-CPA (e.g., Digikey #MAX1771EPA-ND)
T1 = IRFU3708 (e.g., Digikey #IRFU3708-ND)
Miscellaneous:
K1,K2 = 2-way PCB terminal block,lead pitch 5mm
L1 = 47µH high current suppressor
coil, (e.g, Digikey # M9889-ND)
PCB.,ref. 054012-1 from The PCBShop

Author : Unknown - Copyright : Elektor

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How to Make a Bicycle Horn with Ringtone

The old fashioned mechanical bicycle horns are slowly getting discarded now and the folks are more interested to replace them with the musical horns imitating well as phone ringtones. One such project is discussed in this article. The circuit is very easy to build as it incorporates just a couple of active parts and a few other passive parts. The circuit can be operated with 3 volts DC through two penlight AAA size.

Electronic hobbyists who also own a bicycle will love this project. The proposed idea will help you to get rid of your old mechanical bicycle horn with a brand new loud electronic horn. Its a homemade project - another aspect that will amuse the young folks. Lets learn the whole procedure here.

Circuit Description and Construction Clues

Referring to the figure we can see how simple it is to construct the proposed circuit as it utilizes very few electronic parts. The transistor T1 is an ordinary general purpose transistor, the well known 8050. An 8050 is more powerful than the usual BC547 types and is able to handle current up to 150 mA comfortably. The transistor also owns the property of having greater hFE levels than other similar types of transistor resulting in better amplification of the music, and yes it is there basically to amplify the music source.

The music source here is the incredible IC UM66 which has an embedded piece of music “written” inside it. It just needs a supply voltage of 3 V (not to exceed) to get going. The pin-outs are also pretty simple to understand. The left one is the negative, center one is the positive and the right leg is the output – simple isn’t that?

Once the relevant supply terminals of the UM66 are assigned to their posts, it starts “singing” right away through its output pin. However, this audio level is very low and needs to be amplified before feeding it to the step-up coil. This is done by T1 as explained above and the amplified signal is sent to the coil.

The coil used here actually acts as a step-up transformer and is primarily used for stepping up the amplified music fluctuations from the transistor T1. The coil just like any other transformer as a primary and a secondary sections, however the sections are not isolated, rather are wound as a single winding with the center tap appropriately pulled out at the relevant calculated step.

The primary and the secondary winding leads are identified by measuring the corresponding resistances using a multi-tester. The leads which show lower resistance is the primary winding, and the one which shows relatively higher value is the secondary winding.

Normally the primary section will indicate a value of around 22 ohms while the secondary shows a value of around 160 ohms. The common lead across the measurements is the center tap and goes to the positive supply.

The piezo plate which is responsible for the actual reproduction of the sound is connected across the secondary winding directly. The terminals of the piezo from the central white area and the outer metal rim, both the areas are solderable, however soldering the connection over the inner circle needs great care, make sure the solder tip is lifted as soon as the solder spot is made, otherwise the white ceramic coating will immediately get burnt reducing some efficiency of the device. Another aspect with the piezo element is its installation or the fixing method.

The fixing is done over a plastic dish or cap having some depth (around 5 mm) and an inner elevated step of about 1.5 mm in height and 1 mm in width, covering the inner bottom edge of the cap (see fig). The inner diameter of the cap is such that the piezo just brushes inside the cap and settles over the elevated step. And it’s exactly how the piezo is placed and stuck inside the cap (see figure).

The sticking can be done by some good quality synthetic rubber based glue (as used for sticking rubber and leathers). The opposite surface of the cap has a central hole of some calculated diameter (say around 7 mm) and it determines the loudness of the generated sound from the piezo element. Varying this diameter of the hole can drastically vary the amplification and sharpness of the music intensity.

Once the entire wiring of the circuit and piezo assembly id completed, the unit can be powered using two penlight cells, which gives the required 3 volts to the circuit. Amazingly even with such low power supply the music intensity can be found to be significantly loud and ear piercing.

However the supply must not be exceeded this value because the IC UM66 cannot tolerate anything above 3 volts. Of course the unit can be used with higher supply voltages, up to 12 volts only if the supply to the IC is checked and regulated to 3 Volts by a resistor and a zener network. With 12 volts supply the amplification becomes very high and in fact becomes very compatible with cars for using as musical reverse horns.

Parts List

All resistors are ¼ watt, CFR, 5 %, unless otherwise stated

R1, R2 = 1 K,

T1 = 8050,

Coil = As shown in the diagram,

COB = UM 66 IC or any other similar type.

Piezo = 27 mm, two terminal type, as shown in the diagram.

PCB = Veroboard or any general purpose PCB.

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