latest 1 Watt Mini Audio Amplifier

The following schematic diagram is very simple mini audio amplifier circuit. The amplifier which use TDA 7052 as the main component, will gain the power output up to 1 Watt . Power supply voltage range for this circuit is about 6-12V for maximum performance and no heatsink required.

Components list:

C1 = 2.2uF/16V electrolytic capacitor
C2 = 100nF ceramic/mono
C3 = 100uF electrolytic
R1 = 1K ohm resistor
R2 = 10K ohm potentiometer
IC = TDA7052
8 pin IC socket

Specifications :

• Gain ~ 30 dB maximum.
• D.C. input : 3 – 15 V at <>
• Idle current <> 1 Watt @ 8 ohms maximum.
• ~ 10 – 50 kHz, – 3dB
• > 0.25 Watt RMS continuous
• Freq. Resp. > 20 Hz – 20 kHz
• THD <> 70 dBA
• Input Z ~ 10 k ohm.

The kit of this circuit available at electronickits.com, visit the website to buy the kit.
The tutorial for this mini audio amplifier available in PDF format, download the file here.

Download TDA7052 datasheet HERE

latest new 2W Mini Amplifier circuit

he following circuit is inexpensive, easy and very simple. Generally, this audio amplifier that can be used for computer, CD player or other devices that have a headphone output.

Schematic Diagram:

Component part list:
P1 = 10K Log.Potentiometer
R1, R2 = 33K
R3 = 33R
R4 = 15K
R5,R6 = 1K
R7 = 680R
R8 = 120R
R9 = 100R Trimmer Cermet

C1,C2 = 10uF/63V
C3 = 100uF/25V
C4,C7 = 470uF/25V
C5 = 47pF
C6 = 220nF
C8 = 1000uF/25V

D1 = 1N4148

Q1 = BC560C
Q2 = BC337
Q3 =TIP31A
Q4 = TIP32A

SW1 = SPST switch

SPKR 3-5 Watt Loudspeaker, 8, 4 or 2 Ohm impedance

Technical data:

• Output power: 1.5 Watt RMS @ 8 Ohm, 2.5 Watt @ 4 Ohm, 3.5 Watt @ 2 Ohm (1KHz sinewave)
• Sensitivity: 100mV input for 1.5W output @ 8 Ohm
• Frequency response: 30Hz to 20KHz -1dB
• Total harmonic distortion @ 1KHz & 10KHz: Below 0.2% @ 8 Ohm 1W, below 0.3% @ 4 Ohm 2W, below 0.5% @ 2 Ohm 2W.

Source: 2 Watt Mini Audio Amplifier

HA13118: 18W Audio Amplifier

The following circuit is a 18W audio amplifier based on HA13118 which is designed for car audio system. You may use this circuit for home audio sound system.

Resistors :
R1, R2 = 2R2 ohm

Capacitors :
C1, C2, C4, C5, C6 = 100uF/16V
C3 = 10uF/16V
C7, C8, C12 = 100nF
C9 = 2,200uF/25V
C10 = 1uF/50V
C11 = 100pF

Misc.
I.C. = HA13118
Heatsink

About HA13118:
The HA13118 is a power IC which is designed for component car stereo amplifiers. At 13.2 V to 4 ? load, this power IC provides an output power of 18W with 10% distortion.

HA13118 Features:
- Small outline package, easy to mount
- Internal each protection circuits
- Surge protection circuit
—– Thermal shut-down circuit
—– Ground fault protection circuit
—– Power supply fault protection circuit

Download the complete explanation about 18W Audio Amplifier circuit HERE
Download HA13118 datasheet HERE

AC Powered LED Circuit LED Circuit AC Powered compact design

AC Powered LED

The following LED circuit is a compact design using supplied with ac power. LED circuit is very useful as an indicator light on the AC power source voltage 100-240V AC.

LED circuit is quite efficient because it does not need to pay extra for the step-down transformers. However, LED circuits need to be stored in a plastic box for safe to use.

LED circuit is also quite resistant to voltage spikes and surges. As an indicator light should use bright LED colors, like blue and white.

AC Powered LED Circuit

AC Powered LED Circuit LED Circuit AC Powered compact design

AC Powered LED

The following LED circuit is a compact design using supplied with ac power. LED circuit is very useful as an indicator light on the AC power source voltage 100-240V AC.

LED circuit is quite efficient because it does not need to pay extra for the step-down transformers. However, LED circuits need to be stored in a plastic box for safe to use.

LED circuit is also quite resistant to voltage spikes and surges. As an indicator light should use bright LED colors, like blue and white.

AC Powered LED Circuit

latest DC to DC Converter 12V to 120V

Here is a simple DC DC converter schematic using a saturation-limited to push-pull converter. DC converter can be used to power the VCR from a car battery and glow plug light aircraft models from a 12V battery starter.

As a final amplifier of the DC DC converter is a pair of transistor MJE2955 and 2SC945 as oscillator to apply sufficient bias to the final amplifier transistors.

The 2SC945 is a bias switch for startup. When applying 12V power, this transistor applies enough bias to the power transistors to get the oscillation started. Soon later, the 100uF capacitor charges up, the transistor goes off, and the power transistors self-bias into cut-off, such that cross-conduction is eliminated. After removing power, the 6k8 resistor discharges the bias timing capacitor, as otherwise the circuit would be unable to restart!

The secondary rectifiers are ultrafast diodes. These are NOT 1N4007! And the 220nF capacitors for the secondary filter are no typos; the diodes deliver almost pure DC, since the oscillation waveform is square, so only some noise filtering is needed. No electrolytics are necessary here.

DC DC Converter

Note the filters at both input and output, using ferrite cores. These are necessary to avoid polluting your environment with RF noise! Using these filters, and joining the input and output negative leads, this converter is very quiet and does not cause any problem in my combined HF, VHF and UHF station.

All ferrite cores (for the transformer and for the noise filters) are manufactured by Amidon Associates, and can be ordered directly from them in small quantities. Look for Amidon on the web. The 77-material core used for the transformer is less than ideal. A square-loop ferrite would work more efficiently! This one gets really warm, operating in saturation mode at 25 kHz. But it has worked well enough for two years now. The filter cores, on the other hand, are well chosen, so try to use the exact ones.

For all windings, the schematic states the number of turns. “7t” means 7 turns. As the transformer is quite small for the involved power, use as thick a wire as you can fit, leaving about half of the space for the 2×7 turns primary winding, and the other half for the secondary, while the feedback winding can be made from very thin wire.

The transistors do not need any heat sinks. They are large enough without, and they need to dissipate little heat!

S: circuitelectronic.net/dc-dc-converter/

24-Pin DIP Socket Used for Making Atari Cartridge overview and explanation

Overview

This project shows how an Atari cartridge was modified using a 24-pin dual inline package socket in order to become familiar with some Atari programming and possibly sell some homemade cartridges.

Explanation

The 20-year old Atari program is a challenge for those who wish to reprogram it due to its limitation in the size of the game where there is only 2k or 4k along with the memory and CPU power deficiency. Inside the Atari, games are programmed in assembly language for 6502 processor. This is one way of learning more about assembly/game programming even by initially doing a simple graphical output.

An old ISA I/O controller card taken from a Playstation mod was used since it contains lots of jumpers on it which can be useful between the two types of EPROMs, the 2732 and 2532. A piece of paper was used to draw how pins were being routed and how they will be routed for the 2732 EPROM support which involves cutting down to 3 jumpers or 6 pins. A few more traces were cut on the board and the specification becomes the basis of re-soldering

Test Routine For RS232 Communication

Overview

This project illustrates the RS232 transmission and reception for PIC16F84 microcontroller, which is fully controlled by software.

Explanation

During operation, the received ASCII characters are that are sent from PC through RS232 are displayed on the LCD along with their corresponding decimal value. The feedback of received characters is sent back by the microcontroller to the terminal window. The code size is approximately 566 instruction words. A status message ‘@’ is being sent to the PC every 2.75 seconds when the PIC terminal is idle.

A dot matrix LCD display and a MAX232 for RS232 transmission is used by the PCB test board for PIC16F84. The test setup uses LCD display on PortB and asynchronous RS232 connection. The connector at the back consists of RS232 to USB 1.1. After the reset, a welcome screen of the program is seen on LCD display. The start-up message of the RS232 test routine can be seen in the screen shot of the HyperTerminal Program.

The device has a clock frequency in the hands of a 4MHz crystal with 1 MIPS throughput. The acquisition methodology is interrupt-based RS232 with LCD display and RS232 echo during normal operation.

Kinetic Sound Sculpture with Tipping Point

Overview

This project is a toy which converts heat energy into kinetic energy like a thermodynamic heat engine as it consists of a 4x4 gird of 16 “drinking bird” toys.

Explanation

A chemical, known as methylene chloride, with a very low boiling point is the blue fluid inside the toy. The playback cycle begins when the head of the toy bird is saturated with water. The methylene chloride inside condense as the head cools when the water evaporates. A pressure differential between the head and the body is created by this in which the fluid is forced up through the body into the head. The center of gravity shifts and the toy tilts once enough fluid has passed into the head. This allows more water from the glass to be taken up as the internal fluid is allowed to flow back down into the body, then repeating the whole cycle.

The playback of an audio file of a significant speech is controlled by a tilt switch to which each toy is wired. At the start of each tilt event, the audio spins up from zero to full speed and vice versa.

Camera Battery Charger for Train Mounted This camera battery charger circuit will keep the battery for a train mounted camera charged and will shut t

This camera battery charger circuit will keep the battery for a train mounted camera charged and will shut the camera off after a few seconds when power is no longer applied to the track.

This camera battery charger circuit is designed for DCC systems and the battery is essentially used as a capacitor as it is not allowed to become discharged.

The battery also controls the voltage to the camera as any current passed through R1 that is not needed by the camera is shunted through the battery. This is an inefficient but cheap way to control the voltage. (Circuits Without Pages Of Their Own)

Source: Train Mounted Camera Battery Charger

Lead-Acid Batteries Charger with Solar Panel [Solar Batteries Charger] This Batteries Charger is intended for charging sealed lead-acid batteries with

Lead-Acid Batteries Charger with Solar Panel

This Batteries Charger is intended for charging sealed lead-acid batteries with a solar panel in small and portable applications. The customary diode that prevents the battery from discharging through the solar panel has been replaced by a FET-comparator combination.

The batteries charger will stop charging once a pre-set voltage (temperature compensated) has been reached, and recommence charging when the voltage has dropped off sufficiently. The load is disconnected when the battery voltage drops below 11V and reconnected when it gets back to 12.5V.

Solar Batteries Charger Schematic

The batteries charger circuit has the following features:

• Charges until Vbat = 13.8V (adjustable), then float charges;
• Shuts down load when Vbat <>
• Temperature compensation;
• Will work with cheap and readily available components like LM393 comparators and BUZ11 FETs;
• Uses less than 0.5mA when using TLC393 comparators;
• Burns less than 20mW in FETs when charging at 0,5A. (More expensive FETs with a lower RDSON will yield even better results). Note that the charging current is limited only by the solar panel used.

Solar Batteries Charger PCB

Note that I added three DC/DC-converters (for 9, 6 and 3V) on the PCB, the actual charger is less than half of the PCB. I don't have a silk screen, so if you want to build this, you'll have to figure out the PCB for yourself.

With all the components into place, some additional electronics to get the DC/DC-converters in and out of standby, two small SLA-batteries (2.2Ah each), some odd parts and wiring, a fuse, a front plate and housing.

A final word: you build everything at your own risk, no functionality is implied, the resulting apparatus might not work, be unfit for drying pet dogs, and contain small parts that could suffocate children when swallowed or inhaled.

Source: Solar charger for lead-acid batteries

Fire Alarm Using Thermistor In this fire alarm circuit, a thermistor works as the heat sensor. When temperature increases, its resistance decreases,

In this fire alarm circuit, a thermistor works as the heat sensor. When temperature increases, its resistance decreases, and vice versa. At normal temperature, the resistance of the thermistor (TH1) is approximately 10 kilo-ohms, which reduces to a few ohms as the temperature increases beyond 100°C. The circuit uses readily available components and can be easily constructed on any general purpose PCB.

Timer IC NE555 (IC1) is wired as an astable multivibrator oscillating in audio frequency band. Switching transistors T1 and T2 drive multivibrator NE555 (IC1). The output of IC1 is connected to npn transistor T3, which drives the loudspeaker (LS1) to generate sound. The frequency of IC1 depends on the values of resistors R5 and R6 and capacitor C2.

When thermistor TH1 becomes hot, it provides a low-resistance path to extend positive voltage to the base of transistor T1 via diode D1 and resistor R2. Capacitor C1 charges up to the positive voltage and increases the ‘on’ time of alarm. The higher the value of capacitor C1, the higher the forward voltage applied to the base of transistor T1 (BC548).

Since the collector of transistor T1 is connected to the base of transistor T2, transistor T2 provides positive voltage to reset pin 4 of IC1 (NE555). Resistor R4 is used such that IC1 remains inactive in the discharging of capacitor C1 when the thermistor connected to the positive supply cools down and provides a high-resistance (10-kilo-ohm) path. It also stops the conduction of T1. To prevent the thermistor from melting, wrap it up in mica tape.

The circuit works off a 6V-12V regulated power supply. LED1 is used to indicate that power to the circuit is switched on.

Source

Proximity Detector Using CS209 This is a simple proximity detector using IC CS209. The CS209A is a bipolar monolithic integrated circuit for use in m

This is a simple proximity detector using IC CS209. The CS209A is a bipolar monolithic integrated circuit for use in metal detection/proximity sensing applications.The CS209A contains an oscillator set up by an external parallel resonant tank and a feedback resistor connected between pin 2 & 3.

The internal oscillator operates close to the resonant frequency of the tank circuit.As a metal object is brought close to the inductor, the amplitude of the voltage across the tank gradually begins to drop. When the envelope of the oscillation reaches a certain level, the IC causes the outputs to toggle states.potentiometer connected between pin 1 & 8 is adjusted to achieve a certain detection distance range. The larger the resistance the greater the trip-point distance.

Detection range can be incresed by using a high Q coil.Maximum possible range is 1 inch with a well tuned circuit.Only difficulty in making this circuit is the tuning up the circuit to a particular range.For making it easy place a metal piece at the desired distance from coil (with in 1 inch) and adjust resistance Rf to make one of the outputs ( pin4 or 5) to change state.

CS209 Datasheet

12V Battery Charger for Sealed Lead Acid [Deep Cycle SLA Battery] This battery charger is for 12V Seales Lead Acid (SLA) battery. It is actually a hal

This battery charger is for 12V Seales Lead Acid (SLA) battery. It is actually a half-wave rectifier. It only charges the battery on every half cycle. The plug pack doesn't like this as it leaves residual flux in the core of the transformer and causes it to overheat.

There are a number of points we need to cover about the care and use of Sealed Lead Acid batteries.
Firstly, these batteries must be charged, discharged and stored very carefully.
We normally think batteries can be stored for months (if not years) and they will be available for immediate use.

This is not the case with SLA batteries.
If you store a NEW, full charged SLA battery for 6 months or more, you will find it may be fully discharged.
You may also find you cannot charge it!! It may be worthless.
That's how delicate SLA batteries are.

They must be charged on a regular basis to prevent them discharging to a very low voltage level.
If the terminal voltage of a SLA battery is allowed to go below 8v, a process called SULPHATION starts to cover the surface of the plates and prevents the battery being re-charged. The internal resistance of the battery increases and it becomes useless. See products Sealed Lead Acid Battery Charger on Amazon

Parts List of SLA Battery Charger

2 - 1R8 0.5watt resistors
1 - 150R 0.25 watt resistor
1 - 180R
1 - 560R
1 - 1k5
3 - 2k2
1 - 3k3
1 - 4k7
1 - 8k2
1 - 1k mini trim pot

1 - 1n ceramic
2 - 47u 25v electrolytics

1 - 5mm red LED

4 - 1N4148 signal diodes
1 - 10v 0.25watt zener
1 - BC 547 transistor
2 - BC557 transistors
1 - MCR100-6 SCR
1 - 1m red lead
1 - 1m black lead
2 - alligator clips
1 - 2m very fine solder

1 - SLA Battery Charger PCB

Also required:
1 - 12v AC transformer (500mA AC)
1 - power lead
1 - case

Available on Amazon Sealed Lead-Acid Battery Charger
Source : Battery Charger for 12v SLA (Sealed Lead-Acid) Batteries

Dual Power Supply 78xx-79xx series This is a simple dual power supply using voltage regulator IC 78xx and 79xx series. It's the best and simplest choi

This is a simple dual power supply using voltage regulator IC 78xx and 79xx series. It's the best and simplest choice for most non-critical applications. The 3 terminals are input, ground and output. The 78xx & 79xx series can provide up to 1A load current and it have onchip circuitry to prevent damage in the event of over heating or excessive current.

Dual Power Supply Schematic

This dual power supply project provides a dual power supply. With the appropriate choice of transformer and 3-terminal voltage regulator pairs you can easily build a small power supply delivering up to one amp at +/- 5V, +/- 9V, +/- 12V, +/- 15V or +/-18V. You have to provide the centre tapped transformer and the 3-terminal pair of regulators you want: 7805 & 7905, 7809 & 7909, 7812 & 7912, 7815 & 7915or 7818 & 7918.

Note that the + and - regulators do not have to be matched: you can for example, use a +5v and -9V pair. However, the positive regulator must be a 78xx regulator, and the negative a 79xx one. We have built in plenty of safety into this project so it should give many years of continuous service.

These protect mainly against any back emf which may come back into the power supply when it supplies power to inductive loads. They also provide additional short circuit protection in the case that the positive output is connected by accident to the negative output. If this happened the usual current limiting shutdown in each regulator may not work as intended. The diodes will short circuit in this case and protect the 2 regulators.

Dual Power Supply Parts