Imagine we want the automatic sound switch controller. We called the sound activated switch. It has many ways to do these circuits. But now I am going to show you three circuits ideas. I try to combine circuits that are easy for you. And hope you get a benefit.

1. Op-amp Function
2. Ic1a Op Amp Wiring
3. Ic1a Op Amp Diagram

1. The first op-amp IC1A is configured as a non-inverting summing circuit, to sum the voltages from the two inputs. Resistor R12 is used to tie the summing point to ground in case of no inputs. That takes care of Neuron Property #1. In order to implement Neuron Property #2, we need the squashing function.
2. Op Amps Build Simple Multiphase Signal Generator. IC1a is a buffer-follower that allows high-value resistors and low-value capacitors to be used. IC1b is an inverting amplifier with gain.

Op amps IC1a and IC1b carry a pure sinusoidal signal that alternates symmetrically around a direct voltage of 3 V, whereas that of IC1c alternates around 0 V. This means that this op amp can handle an amplification of x 2.2 much better than the earlier two.

Sound activated switch

This is Sound activated switch Circuit with PCB using IC-1458 and SCR-C106D. It will work only if the loud is overdue. Ideal for player cameras Or you can bring it to other users.

It’s not Fouls, such as You may also be applied to a Burglar alarm circuit effectively, or applied to the alarm clock, when it has sounds high level. It operates using electricity tools.

The working of the circuit

When you see advantages its, Might be a good idea now, come look the function of this circuit. As figure shown below. The sound signal is received by the condenser microphone Into the sound signal amplifier circuit That we choose IC op-amp No. MC1458 is Dual OP-Amp IC 8-DIP ST

Or other alternatives:

LF353 is IC Dual Low-Noise JFET OPAMP 3 MHz 8-pin DIP that better quality.

TL072ACP is IC Dual J-FET Op-Amp 8 Pin DIP that cheap and well.

Because the internal structure of the two op-amps, by the shape remains the same IC-741 which the op-amp IC is timeless. Make us cost-effective, convenient, and economical with space.

Come see the circuit to continue. The first op-amp IC1a is designed to gain about ten times, the output of IC1a will enter to pass the R5 to pin 6 of IC1b, that it is designed to gain about 100 times, So the all gain of this circuit is equal to 1,000 times.

The output from IC1b be fed through C2-4.7uF to trigger at pin G of SCR1-C106D works Immediately

Do you know: How SCR works

We use this circuit with the battery 9V, C3 provides a more stable and the C1-10uF placed to minimize disturbance, may cause the circuit to function errors.

How builds it

All devices can be installed onto the PCB, as shown in Figure 2 for the wire MIC, using a shield, to prevent a noise signal, which may make this works errors.

PCB Sound SCR Switch by IC 1458 & SCR C106D

When you installed all parts correctly. Then, try to attach the power supply to the circuit. And then use a small headphone drop across R7, if the circuit work correctly you will hear the sound from your headphone, next to connected the output to Set of the flash lamp of a camera.

Try to clap away from the MIC for about 2-3 inches. The flashlight works immediately but does not works Trial output terminal is connected to the light flash.

Applications

This circuit is designed primarily for use with a camera. However, you may be converted to another use, the output of the circuit to control the relay.

The sensitivity of the circuit can be increased by reducing the value of R1 down to only 22K, it would be more sensitive times.

Stops problems with components and The project not work.
Although the circuits are is not the same. It can produce a sine wave signal as well.

Simple Sound detector circuit using LM324

Today Kunal Banerjee send this project to me. It is a simple Sound detector circuit using LM324. He said ”DEAR SIR, TODAY I HAVE MADE A SOUND DETECTOR CIRCUIT, AND ITS WORKING VERY GOOD AS ITS CAPACITY TO CATCH THE AUDIO IS TOO HIGH AND EASILY DETECT THE SOUND AND THEN IT WORKS.
SO PLEASE ACKNOWLEDGE.

THANKING YOU.”

Figure 1 is the circuit diagram.

The circuit use Mic1 is a condenser microphone, when it gets the sound make the voltage across changing as AC signal and amplified by LM324 op-amp and show the sound with LED1 at the output.

Figure 2 the PCB layout

Figure 3 The component layout.

The single power supply voltage is 5V-12V.

Whistle activated light switch circuit with PCB

Surprisingly much, can turn on – shut down electric devices with a whistling sound.

This is simple sound control circuit as the Whistle activated light switch circuit, that different from a little common circuit is requires high-frequency noise Such as whistle sound etc.

The heart of working in this circuit is IC1 (UM3763) that is designed for this particular work. The figure below shows a circuit in actual use.

How circuit works

The IC1 needs to use a voltage only 3 volts. However, for convenience to using with a voltage relays up to 12V. I so use the R3 and the ZD1 is a reduced voltage for IC1 to only 3 V, as need.

We use R6 to adjust the frequency of the oscillator circuit internal IC1. In this case, sets the frequency at 18Khz. Input frequency using be in the range 1/10 – 1/15 of the frequencies in above. In the frequency between 1.8kHz to 1.2kHz.

The output of the circuit will change state each time to get an input signal comes. The output signal at pin 8 goes to the base of Q1 to drive the output of the transistor Q2, which acts as a relay to drive the pace of the sound input signal.

Parts detail

IC1: UM3763__Analog IC – Datasheet Reference
Q1: NIO is BC547, 45V 100mA NPN Transistor
Q2:bBC337 50V 800mA NPN Transistor
0.25W Resistors, tolerance: 5%
R1: 4.7K
R2: 100 ohms
R3: 2.2K
R4, R5: 1K

C1: 0.0068uF 63V Polyester Capacitor
C2: 4.7uF 16V Electrolytic Capacitors
C3: 10uF 16V Electrolytic Capacitors
D1: DRL is 1N4148 75V 150mA Diodes
ZD1: Zener Diode 3V 0.5W
Relay
Microphone condenser

Note:
The UM3763 is a CMOS LSI circuit which contains analog signal amplifiers and frequency detector for driving motor. It is designed for use in electronic devices and other similar applications. It is packaged with 8 pins DIP.

How to build this project

Figure 2 The PCB and components layout of this project

You put all devices electronic together onto the PCB as circuit diagram correctly complete. As figure 2 You may change the R6 to 1M preset for can adjust circuit in the sound frequency range as you wanted in Easily.

When the circuit finish. Then, check for error again. Next, bring the power to the circuit immediately.

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I always try to make Electronics Learning Easy.

This comprehensive solar charge controller is designed to effectively charge a big 12 V 100 Ah battery with utmost efficiency. The solar charger is practically foolproof in terms of battery over charge, load short circuit, or over current conditions.

The key elements of this 100 Ah solar regulator circuit are, obviously the solar panel and the (12 V) battery. The battery here works as an energy storage unit.

Low voltage DC lamps and stuff like that could be driven straight from the battery, while a power inverter could be operated to convert direct battery voltage into 240 V AC.

Nevertheless, all these applications are generally not the topic of this content, which focuses on hooking up a battery with a solar panel. It may appear too tempting to connect a solar panel directly with the battery for charging, but that's never recommended. An appropriate charge controller is crucial for charging any battery from a solar panel.

The primary importance of the charge controller is to reduce the charging current during peak sunlight when the solar panel resources higher amounts of current beyond the required level of the battery.

This becomes important because charging with high current might lead to critical harm to the battery, and might certainly decrease the battery's working life expectancy.

With no charge controller, the danger of overcharging the battery is usually impending, since the current output of a solar panel is directly determined by the level of irradiation from the sun, or the quantity of incident sunlight.

Essentially, you will find a couple of methods for governing the charging current: through series regulator or a parallel regulator. Manual uninstall beats updater on.

A series regulator system is usually in the form of a transistor which is introduced in series between the solar panel and the battery.

The parallel regulator is in the form of a 'shunt' regulator attached in parallel with the solar panel and the battery. The 100 Ah regulator explained in this post is actually a parallel type solar regulator controller.

The key feature of a shunt regulator is that it doesn't require high amounts of current until the battery is fully charged. Practically speaking, its own current consumption is so less that it can e ignored.

Once the battery is fully charged, however, the excess power is dissipated into heat. Specifically in bigger solar panels, that high temperature requires a relatively huge structure of the regulator.

Along with its real purpose, a decent charge controller additionally provides safety in many ways, together with a protection from deep discharging of the battery, an electronic fuse and a dependable safety towards polarity reversal for the battery or the solar panel.

Simply because the whole circuit is driven by the battery through a wrong polarity safeguard diode, D1, the solar charging regulator continues to work normally even when the solar panel is not supplying current.

The circuit makes use of the unregulated battery voltage (junction D2 -R4) along with a extremely precise reference voltage of 2.5 V. that is generated using zener diode D5.

Since the charging regulator by itself performs perfectly with a current lower than 2 mA, the battery is barely loaded during night time, or whenever the sky is cloudy.

The minimal current consumption by the circuit is achieved by using power MOSFETs type BUZ11, T2 and T3, whose switching is voltage dependent, this allows them to function at practically zero drive power.

The proposed solar charge control for 100 Ah battery monitors the battery voltage and regulates the conduction level of transistor T1.

The bigger the battery voltage, the higher will be the current passing via T1. As a result, the voltage drop around R19 becomes higher.

This voltage across R19 becomes the gate switching voltage for MOSFET T2, which causes the MOSFET to switch harder, dropping its drain-to-source resistance.

Due to this the solar panel gets loaded more heavily which dissipates the excess current through the R13 and T2.

Schottky diode D7 protects the battery from accidental reversal of the + and - terminals of the solar panel.

This diode additionally stops flow of current from the battery into the solar panel in the event the panel voltage falls under the battery voltage.

How the Regulator Works

The circuit diagram of the 100 Ah solar-charger regulator can be seen in the figure above.

The primary elements of the circuit are a couple of 'heavy' MOSFETs and a quadruple op amp IC.

The function of this IC, could be divided into 3 sections: the voltage regulator built around IC1a, the battery over-discharge controller configured around IC1d and the electronic short-circuit protection wired around IC1c.

IC1 works like the main controlling component, while T2 functions as an adaptable power resistor. T2 along with R13 behaves like an active load at the output of the solar panel. The functioning of the regulator is rather simple.

A variable portion of the battery voltage is applied to the non-inverting input of control op amp IC1a through voltage divider R4-P1-R3. As discussed earlier, the 2.5-V reference voltage is applied to the inverting input of the op amp.

The working procedure of the solar regulation is quite linear. The IC1a checks the battery voltage, and as soon as it reaches the full charge, it switches ON T1, T2, causing a shunting of the solar voltage via R13.

This ensures that the battery is not over loaded or over charged by the solar panel. Parts IC1b and D3 are used for indicating the 'battery charging' condition.

The LED illuminates when the battery voltage reaches 13.1V, and when the battery charging process is initiated.

How the Protection Stages Work

The opamp IC1d is set up like a comparator to monitor the battery low voltage level, and ensure protection against deep discharge, and MOSFET T3.

The battery voltage is very first proportionately dropped down to around 1/4 of the nominal value by resistive divider R8/R10, after which it is compared with a reference voltage of 23 V obtained via D5. The comparison is carried out by IC1c.

The potential divider resistors are selected in such a way that the output of IC1d dips lower once the battery voltage falls below a approximate value of 9 V.

MOSFET T3 subsequently inhibits and cuts off the ground link across the battery and the load. Due to the hysteresis generated by the R11 feedback resistor, the comparator doesn't change state until the battery voltage has reached 12 V again.

Electrolytic capacitor C2 inhibits the deep-discharging protection from getting activated by instantaneous voltage drops due to, for example, the switching on of a massive load.

The short-circuit protection included in the circuit functions like an electronic fuse. When a short-circuit accidentally happens, it cuts off the load from the battery.

The same is also implemented through T3, which shows the crucial twin function of the MOSFET T13. Not only does the MOSFET work as a short circuit breaker, its drain-to-source junction additionally plays its part like a computing resistor.

The voltage drop generated across this resistor is scaled down by R12/R18 and subsequently applied to the inverting input of comparator IC1c.

Here, as well, the precise voltage furnished by D5 is utilized as a reference. For so long as the short-circuit protection remains inactive, the IC1c continues to provide a 'high' logic output.

This action blocks D4 conduction, such that the IC1d output solely decides the T3 gate potential. A gate voltage range of around 4 V to 6 V is attained with the help of resistive divider R14/R15, enabling a clear voltage drop to be established over the drain-to-source junction of T3.

Once the load current gets to its highest level, the voltage drop rises quickly until the level is just sufficient to toggle IC1c. This now causes its output to become logic low.

Due to this, now diode D4 activates, allowing the T3 gate to be shorted to ground. Due to this now the MOSFET shuts down, stopping the current flow. The R/C network R12/C3 decides the reaction time of the electronic fuse.

A relatively sluggish reaction time is set in order to avoid incorrect activation of the electronic fuse operation due to occasional momentary high current rise in the load current.

LED D6, in addition, is employed as a 1.6 V reference, making sure C3 is not able to charge above this voltage level.

When the short-circuit is removed and the load detached from the battery, C3 is discharged gradually through the LED (this can take up to 7 seconds). Since the electronic fuse is designed with a reasonably sluggish response, doesn't mean that the load current will be allowed to reach excessive levels.

Before the electronic fuse can get activated, the T3 gate voltage prompts the MOSFET to restrict the output current to the point as determined through the setting of preset P2.

In order to ensure nothing burns or fries, the circuit additionally features a standard fuse, F1, that is attached in series with the battery, and provides reassurance that a probable breakdown in the circuit would not trigger an immediate catastrophe.

As an ultimate defensive shield, D2 has been included in the circuit. This diode safeguards the IC1a and IC1b inputs against damage, due to an accidental reverse battery connection.

Selecting the Solar Panel

Deciding on a most suitable solar panel is, naturally, dependent on the battery Ah rating that you intend to work with.

The solar-charging regulator is basically designed for solar panels with a moderate output voltage of 15 to 18 volts and 10 to 40 watts. These kinds of panels typically become suitable for batteries rated between 36 and 100 Ah.

Nevertheless, since the solar-charging regulator is specified to provide an optimum current draw of 10 A, solar panels rated at 150 watts may well be applied.

The solar charger regulator circuit can be also applied in windmills and with other voltage sources, provided that the input voltage is in the 15-18 V range.

Most of the heat is dissipated through the active load, T2/R13. Needless to say, the MOSFET should be effectively cooled through an heatsink, and R13 should be rated adequately for withstanding extremely high temperatures.

The R13 wattage must in accordance with the rating of the solar panel. In the (extreme) scenario when a solar panel is hooked up with a no-load output voltage of 21 V, and also a short-circuit current of 10 A, in such a scenario T2 and R13 starts dissipating a power equivalent to the voltage difference between the battery and the solar panel (around 7 V) multiplied by the short circuit current (10 A), or simply 70 watts!

This might actually occur once the battery is completely charged. The majority of power is released through R13, since the MOSFET then offers a very low resistance. The value of the MOSFET resistor R13 could be quickly determined through the following Ohm's law:

R13 = P x I² = 70 x 10² = 0.7 Ohms

This sort of extreme solar-panel output could seem unusual, however. In the prototype of the solar-charging regulator, a resistance of 0.25 Ω/40 W had been applied consisting of of four parallel attached resistors of 1Ω/10 W. The necessary cooling for T3 is calculated in the same way.

Supposing that the highest output current is 10 A (that compares to a voltage drop of approximately 2.5 V over the drain-source junction), then a maximum dissipation of about 27W must be evaluated.

To guarantee adequate cooling of T3 even at excessive background temperatures (e.g., 50 °C), the heat-sink must use a thermal resistance of 3.5 K/W or less.

Parts T2, T3 and D7 are arranged at one particular side of the PCB, facilitating them to be easily attached to a single common heatsink (with isolation components).

The dissipation of these three semiconductors must, thus, be included, and we in that case want a heatsink having a thermal specs of 1.5 K/W or higher. The type described in the parts list complies with this prerequisite.

How to Set Up

Op-amp Function

Thankfully, the 100 Ah battery solar regulator circuit is pretty easy to set up. The task does, nonetheless, demand a couple of (regulated) power supplies.

One of them is adjusted to an output voltage of 14.1 V, and coupled to the battery leads (designated 'accu') on the PCB. The second power supply must have a current limiter.

This supply is adjusted to the open-circuit voltage of the solar panel, (for instance 21 V, as in the earlier stated condition), and coupled to the spade terminals designated a 'cells'.

When we adjust the P1 is appropriately, the voltage should decrease to 14.1 V. Please do not worry about this, since the current limiter and D7 guarantee that absolutely nothing can go bad!

For an effective adjusting of P2 you must work with a load that is a little bit higher than the most heavy load that may possibly occur at the output. If you wish to extract the maximum from this design, try picking a load current of 10 A.

This could be accomplished using a load resistor of 1Ω x120 W, made up of, for instance, 10 resistors of 10Ω/10 W in parallel. Preset P2 is in the beginning spun to 'Maximum (wiper towards R14).

After that, the load is attached to the leads designated 'load' on the PCB. Slowly and cautiously fine tune P2 until you achieve the level where T3 just turns off and cuts off the load. After the removal of the load resistors, the 'load' leads can be short-circuited momentarily to test that the electronic fuse functions correctly.

Ic1a Op Amp Wiring

PCB Layouts

Parts List

Ic1a Op Amp Diagram

Resistors:
RI = 1k
R2 = 120k
R3,R20 = 15k
R4,R15,R19 = 82k
R5 = 12k
R6 = 2.2k
R7,R14,R18,R21 = 100k
R8,R9 = 150k
R10 = 47k
R11 = 270k
R12,R16 = 1M
R13 = see text
R17 = 10k
P1 = 5k preset
P2 = 50k preset
Capacitors:
Cl = 100nF
C2 = 2.2uF/ 25V radial
C3 = 10uF/ 16V
Semiconductors:
D1,D2,D4 = 1N4148
D3,136 = LED red
D5 = LM336Z-2.5
D7 = BYV32-50
T1 = BC547
T2,T3 = BUZ11
IC1 = TL074
Miscellaneous:
F1 = fuse 10 A (T) with PCB mount holder
8 spade terminals for screw mounting
Heatsink 1.251VW