Sunday, August 31, 2014

Full Rail Excursions Line driver Wiring diagram Schematic

Full Rail Excursions Line driver Circuit Diagram. This is a Line driver provides full rail excursions schema diagram. The logic input is applied to opt-isolators Ul and U2 with, respectively, npn and pnp emitter follower outputs. Dc balance is adjusted by potentiometer R2. The emitter followers drive the gates of Ql and Q2, the complementary TMOS pairs. 

With a ±12 V supply, the swing at the common source output point is about 12 V peak-to-peak. By adding a ± 18-V boost schema, as shown, the output swing can approach the rail swing. This schema applies the output to transformer Tl, which is rectified by diode bridge D3, regulated by U3 and U4, and then applied to the collectors of Ul and U2. Diodes Dl and D2 are forward-biased when 12-V supplies are used, but they are back-biased when the 18-V boost is used.

Full Rail Excursions - Line driver Circuit Diagram


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The Risks of Self Installation of your Auto Sound System

The risks of installing your own auto sound system may be greater than you realize. The fact is that there are people that are professionally trained in the installation and proper handling of these delicate sound systems for a reason. If it werent a difficult task they wouldnt be able to demand the rather hefty price tag that most installation centers charge. The problem is that mistakes can actually cost more than the installation. If you arent one hundred percent certain that you can handle the installation process alone it is best to leave it up to the experts.

To prove my point, I will give you my very own personal story of how auto sound system installations can go horribly (well, perhaps hilariously would be the better choice of words in my particular situation) of course. You see I wanted a CD player in my mini van about 13 years ago. This was back in the dark ages when these types of sound systems were still relatively new and on the cutting edge when it came to technology.

These types of auto sound systems were definitely not the norm as they are in todays cars. I was commuting 3 hours (round trip) each day at the time and some of the time was spent among the corn fields where there were no towers broadcasting radio signals anywhere nearby. Im sure you can see why I felt I needed a CD player. At any rate, my wonderful dear old dad installed my brand new car (well mini van) stereo for me and all seemed to be going well until we realized that the horn no longer worked and that in order to actually use the stereo, the headlights must be on (this was also before daytime running lights were the norm as well).


Now that youve finished laughing Im sure you can understand why I am a huge advocate for having professional handle issues of installation when it comes to auto sound systems. It isnt that my dad, whom I love dearly for the effort, was incompetent when it comes to technical matters, in fact, he is highly skilled in these sorts of things ordinarily, it is simply that car stereos are so terrible complicated that it takes more than merely reading a set of instructions in order to get the maximum effect from your installation endeavors.



I have heard horror stories, particularly related to in dash installations that have resulted in some people having to make serious and costly repairs to their cars in order to fix the damage inflicted by installations by those who either lacked the proper tools, proper training, or a little bit of both for installing auto sound systems. While some drivers dont spend all that much time in their vehicles on any given day there are many commuters who put many miles on their cars, trucks, or SUVs during the course of a week. For these drivers it is often very important that they have the best possible sound systems for their vehicles. They will rely on their stereos to find out about weather conditions, traffic tie-ups, news, and possibly even entertainment during their long drives. If sound and music plays an important role in your life, dont you deserve the best auto sound system possible?


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2x30W DUAL QUAD POWER AMPLIFIER FOR CAR RADIO TDA7377

Features:

  • HIGH OUTPUT POWER CAPABILITY:
  • 2 x 35W max./4Ω
  • 2 x30W/4Ω EIAJ
  • 2 x30W/4Ω EIAJ
  • 2 x 20W/4Ω @14.4V, 1KHz, 10%
  • 4 x 6W/4Ω @14.4V,1KHz, 10%
  • 4 x 10W/2Ω @14.4V, 1KHz, 10%
  • MINIMUM EXTERNAL COMPONENTS
  • COUNT:
  • – NO BOOTSTRAP CAPACITORS
  • – NO BOUCHEROT CELLS
  • – INTERNALLY FIXED GAIN (26dB BTL)
  • ST-BY FUNCTION (CMOS COMPATIBLE)
  • NOAUDIBLEPOPDURINGST-BYOPERATIONS
  • DIAGNOSTICS FACILITY FOR:
  • – CLIPPING
  • – OUT TO GND SHORT
  • – OUT TO VS SHORT
  • – SOFT SHORT AT TURN-ON
  • – THERMAL SHUTDOWN PROXIMITY
  • Protections:
  • OUPUT AC/DC SHORT CIRCUIT
  • – TO GND
  • – TO VS
  • – ACROSS THE LOAD
  • SOFT SHORT AT TURN-ON
  • OVERRATING CHIP TEMPERATURE WITH
  • SOFT THERMAL LIMITER
  • LOAD DUMP VOLTAGE SURGE
  • VERY INDUCTIVE LOADS
  • FORTUITOUS OPEN GND
  • REVERSED BATTERY
  • ESD
Circuit Diagram:
2x30W DUAL AMPLIFIER aplication circuit

2x30W QUAD AMPLIFIER aplication circuit

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Creating a stereo amplifier with TDA2003

Here I make a stereo power amplifier with IC TDA2003, but actually i made it with 2 IC , so that a stereo amplifier . Construction is very simple and easy. I only need 2 TDA2003 mono amplifier circuit , and then combined into one.
Then the transformer ,  the transformer that i use here is the transformer 10A , so that the power released is greater. Grid power amplifier using the former from the box 10A adaptor , :-) decent can still be used . To view the location of components inside the box , see below :


Top

Right

Top - Right

Wow .,.,this amplifier is very good if using a transformer 10A, issued no buzzing sound , and strong for high bass , just nice deehh..,.,,.,.
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Saturday, August 30, 2014

A Simple Hybrid Audio Amplifier Circuit

A Simple Hybrid Audio Amplifier Circuit diagram. The debate still goes on as to which are better, valves or transistors. We don’t intend to get involved in that argument here. But if you can’t make your mind up, you should try out this simple amplifier. This amplifier uses a valve as a pre-amplifier and a MOSFET in the output stage. The strong negative feedback makes the frequency response as flat as a pancake. In the prototype of the amplifier we’ve also tried a few alternative components. For example, the BUZ11 can be replaced by an IRFZ34N and an ECC83 can be used instead of the ECC88. In that case the anode voltage should be reduced slightly to 155 V. The ECC83 (or its US equivalent the 12AX7) requires 2 x 6.3 V for the filament supply and there is no screen between the two triodes, normally connected to pin 9. This pin is now connected to the common of the two filaments.

Project Image :
A

The filaments are connected to ground via R5. If you’re keeping an eye on the quality, you should at least use MKT types for coupling capacitors C1, C4 and C7. Better still are MKP capacitors. For C8 you should have a look at Panasonic’s range of audio grade electrolytics. P1 is used to set the amount of negative feedback. The larger the negative feedback is, the flatter the frequency response will be, but the smaller the overall gain becomes.
Circuit diagram:
simple-hybrid-amp-schema-diagram
Simple Hybrid Audio Amplifier Circuit Diagram

With P2 you can set the quiescent current through T2. We have chosen a fairly high current of 1.3 A, making the output stage work in Class A mode. This does generate a relatively large amount of heat, so you should use a large heatsink for T2 with a thermal coefficient of 1 K/W or better. For L1 we connected two secondary windings in series from a 2x18V/225 VA toroidal transformer. The resulting inductance of 150 mH was quite a bit more than the recommended 50 mH. However, with an output power of 1 W the amplifier had difficulty reproducing signals below 160 Hz. The distortion rose to as much as 9% for a signal of 20 Hz at 100 mW. To properly reproduce low-frequency signals the amplifier needs a much larger coil with an iron core and an air gap. This prevents the core from saturating when a large DC current flows through the coil.

Parts layout:
Parts

Such a core may be found in obsolete equipment, such as old video recorders. A suitable core consists of welded E and I sections. These transformers can be converted to the required inductor as follows: cut through the welding, remove the windings, add 250 to 300 windings of 0.8 mm enamelled copper wire, firmly fix the E and I sections back together with a piece of paper in between as isolation. The concepts used in this schema lend themselves very well to some experimentation. 

The number of supply voltages can be a bit of a problem to start with. For this reason we have designed a power supply especially for use with this amplifier (Quad power supply for hybrid amp). This can of course just as easily be used with other amplifiers. The supply uses a cascade stage to output an unstabilised voltage of 170 V for the SRPP (single rail push pull) stage (V1).



PCB layout:
PCB

During initial measurements we found that the ripple on this supply was responsible for a severe hum at the output of the amplifier. To get round this problem we designed a separate voltage regulator (High-voltage regulator with short schema protection), which can cope with these high voltages. If you use a separate transformer for the filament supply you can try and see if the schema works without R5. During the testing we used a DC voltage for the filament supply. 

Although you may not suspect it from the test measurements (see table), this amplifier doesn’t sound bad. In fact, it is easily better than many consumer amplifiers. The output power is fairly limited, but is still enough to let your neighbours enjoy the music as well. It is possible to make the amplifier more powerful, in which case we recommend that you use more than one MOSFET in the output stage. The inductor also needs to be made beefier. Since this is a Class A amplifier, the supply needs to be able to output the required current, which becomes much greater at higher output powers. The efficiency of the amplifier is a bit over 30%.


Author: Frans Janssens - Copyright: Elektor Electronics
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Heating System Thermostat Circuit


This schema is intended to control a heating system or central heating plan, keeping constant indoor temperature in spite of wide range changes in the outdoor one. Two sensors are needed: one placed outdoors, in order to sense the external temperature; the other placed on the water-pipe returning from heating system schema, short before its input to the boiler.
The Relay contact wiring must be connected to the boilers start-stop control input. This schema, though simple, has proven very reliable: in fact it was installed over 20 years ago at one of my friends home. I know, it is a bit old: but it is still doing its job very well and without problems of any kind.









Parts:

P1 = 1K Linear Potentiometer
R1 = 10R-1/4W Resistor
R2 = 1K-1/4W Resistor
R3 = 3K3 @ 20°C n.t.c. Thermistor (see Notes)
R4 = 2K2 @ 20°C n.t.c. Thermistor (see Notes)
R5 = 10K-1/2W Trimmer Cermet
R6 = 3K3-1/4W Resistor
R7 = 4K7-1/4W Resistors
R8 = 470K-1/4W Resistor
R9 = 4K7-1/4W Resistors
R10 = 10K-1/4W Resistor
C1 = 470µF-25V Electrolytic Capacitors
C2 = 470µF-25V Electrolytic Capacitors
C3 = 1µF-63V Electrolytic Capacitor
D1 = 1N4002 - 100V 1A Diodes
D2 = 1N4002 - 100V 1A Diodes
D4 = 1N4002 - 100V 1A Diodes
D3 = LED Red 3 or 5mm.
Q1 = BC557 - 45V 100mA PNP Transistor
Q2 = BC547 - 45V 100mA NPN Transistor
Q3 = BC337 - 45V 800mA NPN Transistor
J1 = Two ways output socket
T1 = 220V Primary, 12 + 12V Secondary 3VA Mains transformer
PL1 = Male Mains plug &cable
SW1 = SPST Mains Switch
RL1 = Relay with SPDT 2A @ 220V switch Coil Voltage 12V. Coil resistance 200-300 Ohm





When Q1 Base to ground voltage is less than half voltage supply (set by R7 & R9), a voltage is generated across R8 and the driver transistors Q2 & Q3 switch-on the Relay. When Q1 Base to ground voltage is more than half voltage supply, caused when one of the n.t.c. Thermistors lowers its value due to an increase in temperature, no voltage appears across R8 and the Relay is off. C3 allows a clean switching of the Relay. P1 acts as main temperature control.




Notes:

* R3 is the outdoor sensor, R4 the indoor sensor.
* If you are unable to find a 3K3 Thermistor for R3 you can use a 4K7 value instead. The different value can be easily compensated by means of Trimmer R5.
* R5 allows setting the heating system for outdoor temperatures ranging from about +10°C downwards. The higher R5s resistance the hotter the heating system and vice versa.
* The existing boiler thermostat should be set to its maximum value and not bypassed: it is necessary for safetys sake.
* This schema can be dispensed with its differential feature and converted into a simple precision thermostat omitting R3.

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Build a Wideband Antenna Preamplifier Wiring diagram Schematic

Build a Wide-band Antenna Preamplifier Circuit Diagram. This is a Wide-band Antenna Preamplifier Circuit Diagram. This schema has a gain of around 20 dB from 40 to 860 MHz, covering the entire VHF, FM, commercial, and UHF bands. A phantom power supply provides dc to the Preamplifier via the coaxial cable feeding the unit.

Wideband Antenna Preamplifier Circuit Diagram

Wideband

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AC powered LED Indicator



This is an indicator you can use this schema with your Ac electronic items.Here I have used normal Led.Attach purple color connections to the AC line.I suppose this will be a wonderful schema for you.





Note

# This is not a good schema for kids Because here we use 230V So dont try to build this.

# Build this schema on a PCB
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Friday, August 29, 2014

Build a Inexpensive Isolation Transformer Wiring diagram Schematic

Build a Inexpensive Isolation Transformer Impromptus Setup Circuit Diagram. Using two 12-V filament or power transformers, an impromptu isolation transformer can be made for low-power (under 50 W) use in testing or servicing. SOI is an ordinary, duplex ac recept-able. Use heavy-wire connections between the 12-V windings because several amperes can flow.

Inexpensive Isolation Transformer Circuit Diagram


Inexpensive

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555 DC to AC inverter circuit diagram



This is inverter schema diagram.Here I have used famous Transistors TIP41 and TIP42.And the frequency is generated by NE555.By using R4 you can control the frequency.out put voltage is 120V-230V.the frequency is 50Hz.This schema operates with 5V-15V.







Note

# Be careful because you are dealing with 230V.

#This schema is not suitable for kids.

#Use heat sinks for transistors
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Colpitts Oscillator

Colpitts oscillator is very similar to the shunt-fed Hartley oscillator. The principal difference is in the tank circuit. In the Colpitts oscillator, two capacitors are used as replacement coils are divided. Basic oscillator Feedback oscillator colpitts developed using the "electrostatic field" through the capacitor divider network.



Oscillator Colpitts

Colpitts oscillator frequency is determined by two capacitors connected in series and inductors. Voltage to the base provided by R1 and R2 while for emiitor given by R4. Collector voltage given back by connecting to the positive part of the VCC through R3. This resistor (R3) also functions as a collector load. Transistor is connected with the emitter-joint configuration. When the DC power supplied to the circuit, current flows from the negative part of V CC through R4, Q1 and R3. IC currents flowing through R3 causes a decrease in the voltage VC with a positive price. Voltage changes to negative direction are supplied to the top of the C1 through C3. The lower part of C2 positively charged and the voltage flowing to the base voltage so that the IB price rises.

Transistors Q 1 will increasingly berkonduksi until the saturation point. When Q 1 to the saturation point there was no increase in IC and VC changes will also be halted. There is no feedback to the C2. Magnetic fields C1 and C2 will be disarmed through the L1 and the subsequent magnetic field around it will disappear. Emptying flow persists for a moment. C2-chip bottom becomes negatively charged and pieces of the upper positively charged C1. This will reduce the forward voltage of Q 1 and the IC will be decrease. Price V C will begin to rise. This increase will be fed back to the top of the chip C1 through C3. C1 will charge more positive and the bottom of the C2 becomes more negative.

This process continues until Q 1 to the cutoff point. When Q 1 to the cutoff point, no current I C. No feedback voltage to the C1. Combined charge collected on the C1 and C2 stripped through L1. Currents flowing from the bottom of disarmament to the top of C1 C2. C2 negative charge will eventually run out and the magnetic field around L1akan disappeared. Currents that flow continues. C2 puck into the lower positive charge and the chips C1 upper negative charge. Positive voltage on C2 interesting Q 1 of the cutoff region. Furthermore, the IC will begin to flow again and the process starts again from this point.

Feedback energy is added to the tank circuit for a moment on any changes. The amount of feedback on Colpitts oscillator circuit is determined by the "ratio
capacitance "C1 and C2. The price of C1 in this circuit is much smaller than the C2 or C1 X> X C2. The voltage on C1 is greater than C2. By creating a smaller C2 would obtain feedback voltage is greater. But by raising the feedback too high will cause distortion. Usually around 10-50%, the collector voltage is returned to the tank circuit as a feedback.
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6 Watt stereo power amplifier schematic

Basiccally,this amplifier works with the IC, which is where ic is associated with several other components in the supply and use DC voltage, which corresponds to the needs of IC above course on the circuit schematic. For IC , stands intregated circuit used is ic LM379 which has a maximum 6 Watt stereo output. This IC manufactered by NS and with SDIP-14 package. While other components needed in the circuit schematic , you can see components of the list below.
stereo
Component List :

Resistor
R1___________________2K
R2___________________2K
R3___________________33K
R4___________________33K
R5___________________1M
R6___________________1M
R7___________________10R 2W
R8___________________10R 2W

Capacitor
C1___________________4.7uF
C2___________________4.7uF
C3___________________470uF
C4___________________470uF
C5___________________470uF
C6___________________100n
C7___________________100n

IC
IC1___________________LM379
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Thursday, August 28, 2014

Simple Dc Static Switch Wiring diagram Schematic

This is a Simple Dc Static Switch Circuit Diagram. This schema is a static SCR switch for use in a dc schema. When a low power signal is applied to the gate of SCR1, this SCR is triggered and voltage is applied to the load. The right hand plate of C charges positively with respect to the left hand plate through Rl. 

 Simple Dc Static Switch Circuit Diagram

 simple dc static switch circuit diagram


When SCR2 is triggered on, capacitor C is connected across SCR1, so that this SCR is momentarily reverse biased between anode and cathode. This reverse voltage turns SCR1 off provided the gate signal is not applied simultaneously to both gates. The current through the load will decrease to zero in an exponential fashion as C becomes charged.


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Surround Power Amplifier LM3886


Power Amplifier LM3886 
Audio Power Amplifier is an important part in the reproduction of sound in a sound system. Audio Power Amplifier LM 3886 with power IC Audio Power Amplifier is a highly capable and able to produce 68 Watts with power rata2 4Ohm load and capable of producing power 38 Watt with 8Ohm load. 
With good sound reproduction capabilities of 20Hz-20kHz is also included on this LM3886 Audio Power Amplifier. LM3886 Audio Power Amplifier is equipped with spike protection that will protect the output circuit from overvoltage, undervoltage, overloads, konrsleting power supply, thermal runawaydan peak temperature. Audio Power Amplifier LM3886 also features a noise reduction system which can keep the audio from the noise well.

Basic Audio Power Amplifier Series LM3886 





Audio Power Amplifier LM3886 

Feature owned LM3886 Audio Power Amplifier 

68W cont. avg. output power into 4Ω at VCC = ± 28V
38W cont. avg. output power into 8Ω at VCC = ± 28V
50W cont. avg. output power into 8Ω at VCC = ± 35V
135W instantaneous peak output power capability
Signal-to-Noise Ratio ≥ 92dB
An input mute function
Output protection from a short to ground or to the supplies via internal current limiting circuitry
Output over-voltage protection against transients from inductive loads
Supply under-voltage protection, not allowing internal biasing to occur Pls | VEE | + | VCC | ≤ 12V, Thus eliminating turn-on and turn-off transients
11-lead TO-220 package
Wide supply range 20V - 94V
Application of Audio Power Amplifier LM3886
Stereo audio system
Active Speaker
High End Audio Power TV
Suround Power Amplifier
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Burglar Alarm Circuit


This is a very useful schema for you all.This is actually little bit different schema.Because this schema has used little bit advance knowledge.This schema operates with 9V.You can fix this schema for a door(SW1).Its ok though people use this door.But if some one keep opened it more than 30 seconds the alarm begins to ring.only users should know they should closed the door before 30 seconds.Think different way and use this in different way.



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Variable charger circuit

Indeed the accu charger circuit , the voltage required must be in accordance with voltage batteries , such accu 12 volts the the output voltage should not be above 12 volts and 12 volts should not be too down. If it does not comply with the required voltage , it will make the batteries or accu quickly broken. But not to worry to find the right voltage to charge to accu, the voltage control circuit is equipped to facilitate in determining the voltage.
Transformer
Primary : 33 turns #22
Secondary : 45 turns #22
Core : Ferroxcube 203 F 181.3C3
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Wednesday, August 27, 2014

Portable Battery Charger Circuit

This circuit was designed to charge Nicad battery packs in the range of 4.8 to 15.6 V from a convenient remote power source , such as automobile battery. When power is first applied to the circuit applied to the circuit , a small bias current supplied by R1 via winding L1 , starts to turn on the transistor TR1.
portable
This forces a voltage across L2 and the positive feedback given by the coupling of L1 and L2 causes the transistor to turn hard on , applying the full supply across L2. The base drive voltage induced across L1 makes the junction the necessary base current to hold Q1 on.
Component List

Resistor
R1 = 1M
R2 = 120R
R3 = 10R
R4 = 39R

Capacitor
C1 = 100uF 25V
C2 = 0.01uF
C3 = 4700pF
C4 = 100uF 25V

Diode
D1 = 1N4148
D2 = BYV27-5
D3 = BYV27-5

Transistor
Q1 = ZTX650

Transformer
L1 = 12T 36awg
L2 = 13T 36awg
L3 = 20T 30awg
L4 = 40T 30awg
Core FX3437 with gap of 0.08mm
Former DT2492
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USB powered battery charger circuit

rangkaian
At this time I will share about the series used in the usb to charge battery. Issued voltage 4.7 Volt to 5 Volt DC suitable for battery charge the phone, as well as other batteries. 




Below is a circuit where the voltage is removed the usb on the computer will be strengthened by several components so that the voltage used to charge batteries more powerful and filtered, and will make it more durable and long lasting.
USB
Part List :
R1 = 1 K
R2 = 330 R
R3 = 4K7
R4 = 300 R
R5 = 27R
D1 = 4.7 volt zener /1W
C1 = 100uF/16V
Q1 = BC548
Q2 = BC558A
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56W High Audio Amplifier Use LM3875 Wiring diagram Schematic

This is a simple 56W High Audio Amplifier Use LM3875 Circuit Diagram. The LM3875 is an audio amplifier for high power output capable of delivering 56W of continuous average power to a load 8. The performance of the LM3875, utilizing its maximum instantaneous auto temperature (° Ke) (Spike ™) protection schemary, places it in a class above discrete and hybrid amplifiers by providing a yes, dynamically protected area of safe operation (SOA). SPIKE protection means that these parts are fully protected against output overvoltage, voltage surges caused by shorts to the supplies, the peak temperature thermal runaway, and instantaneous.

56W High Audio Amplifier Use LM3875 Circuit Diagram

 

 56W

This amplifier schema is based on the non-inverted GainClone standard configuration. I did some calucaltions the feedback resistor and other components in order to check the gain, etc. For more background on the calculations relevant to GainClones in the background section.



Parameters IC LM3875

Output Current 6000 mA.
Offset Voltage max, 25C 10 mV.
Gain Bandwidth 8 MHz.
Supply Min 20 Volt.
Supply Max 84 Volt.
Supply Current Per Channel 30 mA.
PowerWise Rating 2 3750 uA/MHz.
Slew Rate 11 Volts/usec.
Input OutputType Not Rail to Rail.
Max Input Bias Current 1000 nA.
Special Features AvCl>10.
Function Op Amp.
Channels 1 Channels.
Temperature Min 0 deg C.
Temperature Max 70 deg C


Sourced By : Circuitsstream
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ANTI THEFT ALARM AND HORN

Here is a simple ANTI-THEFT ALARM AND HORN. It generates a loud alarm when there is an attempt of theft. When the intruder opens the door, the schema senses the attempt of theft and after 2 minutes, the alarm will be activated. The time delay is provided to help the user to leave after arming with the device.

 ANTI-THEFT ALARM AND HORN


ANTI-THEFT
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Tuesday, August 26, 2014

Battery Powered Night Lamp


This schema is usable as a Night Lamp when a wall mains socket is not available to plug-in an ever running small neon lamp device. In order to ensure minimum battery consumption, one 1.5V cell is used and simple voltage doublers drives a pulsating ultra-bright LED: current drawing is less than 500µA. An optional Photo resistor will switch-off the schema in daylight or when room lamps illuminate, allowing further current economy. This device will run for about 3 months continuously on an ordinary AA sized cell or for around 6 months on an alkaline type cell but, adding the Photo resistor schemary, running time will be doubled or, very likely, triplicates. IC1 generates a square wave at about 4 Hz frequencies. C2 & D2 form voltage doublers, necessary to raise the battery voltage to a peak value able to drive the LED.





Parts:

R1 = 1M
R2 = 1M
R3 = 47K
R4 = LDR
C1 = 100nF-63V
C2 = 220uF-25V
D1 = Ultra Bright 10mm LED
D2 = 1N5819 B1 = 1.5V Battery or AA Cell
IC1 = 7555 CMos Timer IC



Notes:



* IC1 must be a CMos type: only these devices can safely operate at 1.5V supply or less. * If you do not need Photo resistor operation, omit R3 & R4 and connect pin 4 of IC1 to positive supply. * Ordinary LEDs can be used, but light intensity will be poor. * An ordinary 1N4148 type diode can be used instead of the 1N5819 Schottky-barrier type diode, but LED intensity will be reduced due to the higher voltage drop. * Any Schottky-barrier type diode can be used in place of the 1N5819, e.g. the BAT46, rated @ 100V 150mA.

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Basic Oscillator Circuit using Two Transistors

Basic

This is the schematic diagram of basic oscillator schema which using two transistors. When two transistors and a couple of passive components are connected as shown in the figure, the schema starts to oscillate. The frequency of oscillation can be adjusted by changing the values of either the resistor or the capacitor.

For easier experiment, you may replace the resistor with 10K potensiometer. By increasing its frequency to a suitably high level, it can be used to drive a speaker or a buzzer to produce an audio alarm note. By sufficiently reducing its frequency, the schema may be used to flash a LED as a warning indicator.

The another schema of two transistors oscillator described in the following video:

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Simple Proportional Temperature Controller Wiring diagram Schematic

This temperature controller operates as a pulse snatching device, which allows it to run at its own speed and tum on at the zero crossing of the line frequency. Zero crossing tum-on reduces the generation of line noise transients. TMOS Power FET, Ql, is used to tum on a heater. Temperature sensor D6 provides a de voltage proportional to temperature that is applied to voltage-tofrequency converter Ul. Output from Ul is a pulse train proportional to temperature offset that is applied to the input of triac optoisolator U2.

Simple Proportional-Temperature-Controller Circuit Diagram


Simple

The anode supply for the triac is a 28 V pk-pk, full-wave rectified sine wave. The optoisolator ORs the pulse train from Ul with the zeroTrossing of U2`s anode supply, supplying a gate tum on signal for Ql. Therefore, TMOS power FET Ql can only tum the heater on at the zero crossing of the applied sine wave. The maximum temperature, limited by the sensor and the insulation of the wire, is 130°C for the components shown. 
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Hi Fi 25W Power Amplifier Class A

Hi-Fi 25W Power Amplifier (Class-A) Schematics Circuit
Hi-Fi
Click to view larger
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Monday, August 25, 2014

4 x 30W QUAD BRIDGE CAR RADIO AMPLIFIER

Description

The TDA7383 is a new technology class AB Audio Power Amplifier in Flexiwatt 25 package designed for high end car radio applications.

Circuit Diagram
4 x 30W QUAD BRIDGE CAR RADIO AMPLIFIER


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Pioneer Video Bypass

Since the high demand for the Pioneer parking brake bypass; I have decided to come up with a easy diagram for you to follow which will allow you to play videos while you are in motion.

1.  Connect the blue system turn on (Remote) wire to spade #85 (If you have or installing and amplifier connect your amplifier turn on (Remote) wire to this prong also)

2. Connect a grounding wire to spade # 87 which jumps and connects to spade # 86. Then connect the wire to a good ground.

3. Connect the parking brake wire from the head unit (Green Wire) to spade # 30

4. Finish installing your stereo and enjoy your video.



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AIWA XH A1060 COMPACT DISC STEREO SYSTEM SCHEMATICS

AIWA XH-A1060 COMPACT DISC STEREO SYSTEM - Circuit Diagram
BASIC TAPE MECHANISM: 6ZM-1 AR3N1M
BASIC CD MECHANISM: AZG-1 YZD3RDM
POWER
TUNER
AMP
SUB-WOOFER
CLICK ON THE PICTURES TO ZOOM IN

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Hold The Phone With Music


This is so useful schema for us Because If our caller is in hold on position we can allow them to listen a music.When you want to operate this schema you can hold on your phone and switch on the S1. The RED wire from the phone jack is typically positive and the GREEN wire is negative or ground.







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Sunday, August 24, 2014

Build a 300 Watt Subwoofer Power Amplifier Wiring diagram Schematic

The output devices are MJL4281A (NPN) and MJL4302A (PNP), and feature high bandwidth, excellent SOA (safe operating area), high linearity and high gain. Driver transistors are MJE15034 (NPN) and MJE15035 (PNP). All devices are rated at 350V, with the power transistors having a 230W dissipation and the drivers are 50W.

Having built a P68 using these transistors, I recommend them highly - the amplifier is most certainly at its very best with the high gain and linearity afforded by these devices. Note that there are a few minor changes to the schema (shown below).

High power amps are not too common as projects, since they are by their nature normally difficult to build, and are expensive. A small error during assembly means that you start again - this can get very costly. I recommend that you use the PCB for this amplifier, as it will save you much grief. This is not an amp for beginners working with Veroboard!

The amplifier can be assembled by a reasonably experienced hobbyist in about three hours. The metalwork will take somewhat longer, and this is especially true for the high continuous power variant. Even so, it is simple to build, compact, relatively inexpensive, and provides a level of performance that will satisfy most requirements.

300W Sub woofer Power Amplifier Circuit Diagram

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Fig 1
WARNINGS:
  • This amplifier is not trivial, despite its small size and apparent simplicity. The total DC is over 110V, and can kill you.
  • The power dissipated is such that great care is needed with transistor mounting.
  • The S300 is intended for intermittent duty on 4 Ohm loads, as will normally be found in a subwoofer. It is NOT intended for PA or any other continuous duty, and although it may work fine for may years, I absolutely do not recommend this.
  • For continuous duty, do not use less than 8 Ohms.
  • There is NO SHORT CIRCUIT PROTECTION. The amp is designed to be used within a subwoofer enclosure, so this has not been included. A short on the output will almost certainly destroy the amplifier.
DO NOT ATTEMPT THIS AMPLIFIER AS YOUR FIRST PROJECT

Please note that this amp is NOT designed for continuous high power into 4 Ohms. It is designed for intermittent duty, suitable for an equalized sub woofer system (for example using the ELF principle - see the Project Page for the info on this schema). Where continuous high power is required, another 4 output transistors are needed, wired in the same way as Q9, Q10, Q11 and Q12, and using 0.1 ohm emitter resistors.

Continuous power into 8 ohms is typically over 150W, and it can be used in the form shown at full power into an 8 ohm load all day, every day. The additional transistors are only needed if you want to do the same thing into 4 ohms!

The schema is shown in Figure 1, and it is a reasonably conventional design. Connections are provided for the Internal SIM (published elsewhere on the Project Pages), and filtering is provided for RF protection (R1, C2). The input is via a 4.7uF bipolar cap, as this provides lots of capacitance in a small size. Because of the impedance, little or no degradation of sound will be apparent. A polyester cap may be used if you prefer - 1uF with the nominal 22k input impedance will give a -3dB frequency of 7.2Hz, which is quite low enough for any sub.
The input stage is a conventional long-tailed pair, and uses a current sink (Q1) in the emitter schema. I elected to use a current sink here to ensure that the amp would stabilise quickly upon application (and removal) of power, to eliminate the dreaded turn on "thump". The amp is actually at reasonably stable operating conditions with as little as +/-5 volts! Note also that there are connections for the SIM (Sound Impairment Monitor), which will indicate clipping better than any conventional clipping indicator schema. See the Project Pages for details on making a SIM schema.
The Class-A driver is again conventional, and uses a Miller stabilisation cap. This component should be either a 500V ceramic or a polystyrene device for best linearity. The collector load uses the bootstrap principle rather than an active current sink, as this is cheaper and very reliable (besides, I like the bootstrap principle :-)

All three driver transistors must be on a heatsink, and D2 and D3 should be in good thermal contact with the driver heatsink. Neglect to do this and the result will be thermal runaway, and the amp will fail.

C11 does not exist on this schematic, so dont bother looking for it. It was "mislaid" when the schematic was prepared, and I didnt notice until someone asked me where and what it was supposed to be. Sorry about that.
It is in the output stage that the power capability of this amp is revealed. The main output is similar to many of my other designs, but with a higher value than normal for the "emitter" resistors (R16, R17). The voltage across these resistors is then used to provide base current for the main output devices, which operate in full Class-B. In some respects, this is a "poor-mans" version of the famous Quad "current dumping" schema, but without the refinements.

Although I have shown MJL4281A and MJL4302A output transistors, because they are new most constructors will find that these are not as easy to get as they should be. The alternatives are MJL21193/ MJL21194
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Fig 2

Note: It is no longer possible to recommend any Toshiba transistors, since they are the most commonly counterfeited of all. The 2SA1302 and 2SC3281 are now obsolete - if you do find them, they are almost certainly fakes, since Toshiba has not made these devices since around 1999~2000.

Use a standard green LED. Do not use high brightness or other colors, as they may have a slightly different forward voltage, and this will change the current sinks operation - this may be a miniature type if desired. The resistors are all 1/4W (preferably metal film), except for R10, R11 and R22, which are 1W carbon film types. All low value resistors (1 ohm and 0.1 ohm) are 5W wire wound types.

Because this amp operates in "pure" Class-B (something of a contradiction of terms, I think), the high frequency distortion will be relatively high, and is unsuited to high power hi-fi. At the low frequency end of the spectrum, there is lots of negative feedback, and distortion is actually rather good, at about 0.04% up to 1kHz.

Power output into 4 ohms is over 250W continuous, and for transients exceeds 300W easily. Use of a big power transformer and massive filter caps will allow the amp to deliver close to 350W continuous, but if you really want to use it like that, I very strongly recommend the additional output transistors (see above comments on this topic).

Power Dissipation Considerations
I have made a lot of noise about not using this amp for continuous duty into 4 ohms without the extra transistors. A quick calculation reveals that at the worst case, the output and transistor voltage will be the same - i.e. at 28V. With 28V, load (and transistor) current is 7A, so the instantaneous dissipation is therefore 28 * 7 = 196W. This means that the four final transistors do most of the work, with the others having a relatively restful time.

Since I like to be conservative, I will assume that they contribute no more than about 1.5A (which is about right). This means that they only dissipate 48W, with the main O/P devices dissipating a peak of 74W each. The specified transistors are 130W, and the alternatives are 150W, so where is the problem?

The problem is simple - the rated dissipation for a transistor is with a case temperature of 25°C. As the amp is used, each internal transistor die gets hot, as does the transistor case - the standard derating curves must be applied. Add to this the reactive component as the loudspeaker drives current back into the amp, and it becomes all too easy to exceed the device dissipation limits.

Figure 1A shows the doubled output stage, with Q9, Q10, Q11 and Q12 simply repeated - along with the emitter resistors. Each 1/2 stage has its own zobel network and bypass caps as shown, as this is the arrangement if the dual PCB version is built. When you have this many power transistors, the amp will happily drive a 4 ohm load all day - with a big enough heatsink, and / or forced cooling (highly recommended, by the way).

A Few Specs and Measurements

The following figures are all relative to an output power of 225W into 4 ohms, or 30V RMS at 1kHz, unless otherwise stated. Noise and distortion figures are unweighted, and are measured at full bandwidth. Measurements were taken using a 300VA transformer, with 6,800uF filter caps. Mains voltage was about 4% low when I did the tests, so power output will normally be slightly higher than shown here if the mains are at the correct nominal voltage.

Gain 27dB
Power (Continuous) 240W (4 ohms)

153W (8 ohms)
Peak Power - 5 ms 185W (8 ohms)
Peak Power - 10 ms 172W (8 ohms)
Input Voltage 1.3V RMS
Noise -63dBV (ref. 1V)
S/N Ratio 92dB
Distortion 0.4%
Distortion (@ 4W) 0.04% (1 Khz)
Distortion (@ 4W) 0.07% (10 kHz)
Slew Rate > 3V/us
Power Bandwidth 30 kHz
These figures are quite respectable, especially considering the design intent for this amp. While it would not be really suitable for normal hi-fi, even there it is doubtful that any deficiencies would be readily apparent, except perhaps at frequencies above 10kHz. While the amp is certainly fast enough (and yes, 3V/us actually is fast enough - full power is available up to 30kHz), the distortion will be a bit too high.

Note that the "peak power" ratings represent the maximum power before the filter caps discharge and the supply voltage collapses. I measured these at 5 milliseconds and 10 milliseconds. Performance into 4 ohm loads will not be quite as good, as the caps will discharge faster. The supply voltage with zero power measured exactly 56V, and collapsed to 50.7V at full power into 8 ohms, and 47.5V at full power into 4 ohms.

Photo
Photo of Completed Prototype

The photo does not show the silk screened component overlay, since this is the prototype board. The final boards have the overlay (as do all my other boards).

As can be seen, this is the single board version. The driver transistors are in a row, so that a single sheet aluminium heatsink can be used for all three. Holes are provided on the board so the driver heatsink can be mounted firmly, to prevent the transistor leads breaking due to vibration. This is especially important if the amp is used for a powered subwoofer, but will probably not be needed for a chassis mounted system.
The driver and main heatsinks shown are adequate for up to 200W into 4 ohms with normal program material. The power transistors are all mounted underneath the board, and the mounting screw heads can be seen on the top of the board.

Deceptively simple, isnt it?

Power Supply

WARNING: Mains wiring must be performed by a qualified electrician - Do not attempt the power supply unless suitably qualified. Faulty or incorrect mains wiring may result in death or serious injury.
The basic power supply is shown in Figure 2. It is completely conventional in all respects. Use a 40-0-40 V transformer, rated at 300VA for normal use. For maximum continuous power, a 500VA or bigger transformer will be needed. This will give a continuous power of about 350W, and peak power of close to 400W is possible with a good transformer. Remember my warnings about using the amp in this way, and the need for the additional output transistors.

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Figure 2 - Basic Power Supply Circuit
For 115V countries, the fuse should be 6A, and in all cases a slow blow fuse is required because of the inrush current of the transformer.

C1 must be rated for 240V AC (or 120V AC) operation - do not use standard 250V DC caps under any circumstance, as they will fail, and R1 will explode! This is not intended as humour - this is fact! C1 and R1 may be omitted in most cases, and if you cannot get a mains rated capacitor I suggest that you dont install these components.

The supply voltage can be expected to be higher than that quoted at no load, and less at full load. This is entirely normal, and is due to the regulation of the transformer. In some cases, it will not be possible to obtain the rated power if the transformer is not adequately rated.

Bridge rectifiers should be 35A types, and filter capacitors must be rated at a minimum of 63V. Wiring needs to be heavy gauge, and the DC must be taken from the capacitors - not from the bridge rectifier.

Although shown with 4,700uF filter capacitors, larger ones may be used. Anything beyond 10,000uF is too expensive, and will not improve performance to any worthwhile degree. Probably the best is to use two 4,700uF caps per side (four in all). This will actually work better than a single 10,000uF device, and will be cheaper as well.

NOTE: It is essential that fuses are used for the power supply. While they will not stop the amp from failing (no fuse ever does), they will prevent catastrophic damage that would result from not protecting the schema from over-current conditions. Fuses can be mounted in fuseholders or can be inline types. The latter are preferred, as the supply leads can be kept as short as possible. Access from outside the chassis is not needed - if the fuses blow, the amplifier is almost certainly damaged.
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