Wiring & diagram Info: light

Showing posts with label light. Show all posts

Saturday, November 15, 2014

LIGHT DETECTOR CIRCUIT

Light detectors are one of the most popular sensor and they are commonly found in many real-world applications. They are widely used by electronic hobbyists and projects because they are practical and intriguing yet surprising easy to construct. This will guide and show you how easy it is to make your own light activated Light Emitting Diode (LED) with minimal tools and materials. The whole project is simple. This implementation can be used for an educational demo or applied directly to the practical world.

Parts

Breadboard or PCB Board
A few Jumper Wires
9 Volts Battery
9 Volts Battery Clip
Light Dependent Resistor (LDR)
Light Emitting Diode (LED) with any color of choice
TLC3704 Quad Comparator (only one of its four comparators will be used) (Alternatively, you can use the single LM311N Comparator with 8pin)
3362P-103-ND 10K Ohms Variable Resistor
1K Ohms (Brown-Black-Red) Resistor X2
330 Ohms (Orange-Orange-Brown) Resistor

Circuit Diagram

Working

As its name suggests, a comparator compares two given voltages. The pair of 1K ohms resistors create a voltage divider and provide a 4.5 volts reference for the comparator. The variable resistor and LDR both form another pair for a second voltage divider. When light falls on the LDR, its resistance lowers and that voltage divider provides a voltage lower than 4.5 volts. The comparator produces no output (0 volts). When light is absent, the resistance of the LDR and the voltage increases. When the voltage increases over 4.5, the comparator activates its output and supplies 9 volts to power the LED.

Wednesday, November 12, 2014

7555 or TS555CN based Courtesy Light circuit

15 seconds delayed switch-off, A good idea for bedroom lamps
This circuit is intended to let the user turn off a lamp by means of a switch placed far from bed, allowing him enough time to lie down before the lamp really switches off. Obviously, users will be able to find different applications for this circuit in order to suit their needs.

Parts :
R1 = 470R 1/2W
R2 = 100K
R3 = 1M5
R4 = 1K
C1 = 330nF-400V
C2 = 100µF-25V
C3 = 10nF-63V
C4 = 10µF-25V
C5 = 10nF-63V
D1 = 1N4007
D2 = 1N4007
D3 = BZX79C10
D4 = TIC206M
Q1 = BC557
IC1 = 7555 or TS555CN CMos Timer IC
SW1 = SPST Mains suited Switch

Circuit operation:
Due to the low current drawing, the circuit can be supplied from 230Vac mains without a transformer. Supply voltage is reduced to 10Vdc by means of C1 reactance, a two diode rectifier cell D1 & D2 and Zener diode D3. IC1 is a CMos 555 timer wired as a monostable, providing 15 seconds on-time set by R3 & C4. When SW1 is closed, IC1 output (pin 3) is permanently on, driving Triac D4 which in turn feeds the lamp. Opening SW1 operates the monostable and, after 15 seconds, pin 3 of IC1 goes low switching off the lamp.

Monday, October 13, 2014

Infrared Light Photo Detector Circuit This is a basic infrared light photo detector circuit In this circuit the light falling on the phototransistor

Infrared Light Photo-Detector Circuit

This is a basic infrared light photo detector circuit. In this circuit the light falling on the phototransistor will be from an Infrared Light Emitting Diode (IrLED) but otherwise it is the same as the phototransistor circuit shown above.

When the light falling on the phototransistor (Q1) is blocked, its conductance will decrease and the voltage across Q1 will rise. When the voltage rises above 1/2 of the supply voltage the output of the comparator will turn ON and the LED will be lit.

Source: Infrared Light Photo-Detector

Thursday, September 4, 2014

Flashy christmas light

This simple and inexpensive schema built around a popular CMOS hex inverter IC CD4069UB offers four sequential switching outputs that may be used to control 200 LEDs (50 LEDs per channel), driven directly from mains supply. Input supply of 230V AC is rectified by the bridge rectifiers D1 to D4. After fullwave rectification, the average output voltage of about 6 volts is obtained across the filter comprising capacitor C1 and resistor R5.

Wednesday, August 27, 2014

Electronic Street Light Switch Circuit Digram

Here’s a simple and low-cost street light switch. This switch automatically turns on the light at sunset and turns it off at sunrise. The automatic function saves electricity besides man-power.

Broadly, the schema can be divided into power supply and switching sections.

Pressing switch S1 connects mains to power the schema. Mains is stepped down to 9.1V DC by resistor R1, diode D1 and zener diode ZD1. The output across ZD1 is filtered by capacitors C1 and C2. The output voltage can be increased up to 18V or decreased to 5V by changing the value of zener diode ZD1.

The switching schema is built around light-dependent resistor LDR1, transistors T1 through T3 and timer IC1. The resistance of LDR1 remains low in daytime and high at night. Timer IC1 is designed to work as an inverter, so a low input at its pin 2 provides a high output at pin 3, and vice versa. The inverter is used to activate triac 1 and turn street bulb B1 on.

Electronic Street Light Switch Circuit Digram

During daytime, light falls on LDR1 and transistors T1 and T2 remain cut-off to make pins 4 and 8 of IC1 low. Since transistor T3 is also cut-off, IC1 is not triggered. As a result, output pin 3 of IC1 (connected to the gate of triac 1 via resistor R5 and red LED1) remains low and the street bulb does not glow.

At night, no light falls on LDR1 and transistors T1 and T2 conduct to make pins 4 and 8 of IC1 high. Due to the conduction of transistor T3, trigger pin 2 of IC1 remains low. The high output of IC2 at its pin 3 turns the street bulb ‘on.’

Assemble the schema, except LDR1, on any general-purpose PCB. Use long wires for LDR1 connections so that it can be mounted at a place where sufficient light falls on it.

Author : Prince Philips

Saturday, August 16, 2014

Emergency Light Alarm

This schema is permanently plugged into a mains socket and NI-CD batteries are trickle-charged. When a power outage occurs, the lamp automatically illuminates. Instead of illuminating a lamp, an alarm sounder can be chosen.When power supply is restored, the lamp or the alarm is switched-off. A switch provides a "latch-up" function, in order to extend lamp or alarm operation even when power is restored.

Emergency Light & Alarm

Parts:
R1____________220K 1/4W Resistor R2____________470R 1/2W Resistor R3____________390R 1/4W Resistor R4______________1K5 1/4W Resistor R5______________1R 1/4W Resistor R6_____________10K 1/4W Resistor R7____________330K 1/4W Resistor R8____________470R 1/4W Resistor R9____________100R 1/4W Resistor C1____________330nF 400V Polyester Capacitor C2_____________10µF 63V Electrolytic Capacitor C3____________100nF 63V Polyester Capacitor C4_____________10nF 63V Polyester Capacitor D1-D5________1N4007 1000V 1A Diodes D6______________LED Green (any shape) D7___________1N4148 75V 150mA Diode Q1,Q3,Q4______BC547 45V 100mA NPN Transistors Q2,Q5_________BC327 45V 800mA PNP Transistors SW1,SW2________SPST Switches SW3____________SPDT Switch LP1____________2.2V or 2.5V 250-300mA Torch Lamp Bulb SPKR___________8 Ohm Loudspeaker B1_____________2.5V Battery (two AA NI-CD rechargeable cells wired in series) PL1____________Male Mains plug Mains voltage is reduced to about 12V DC at C2s terminals, by means of the reactance of C1 and the diode bridge (D1-D4). This avoids the use of a mains transformer. Trickle-charging current for the battery B1 is provided by the series resistor R3, D5 and the green LED D6 that also monitors the presence of mains supply and correct battery charging. Q2 & Q3 form a self-latching pair that start operating when a power outage occurs. In this case, Q1 biasing becomes positive, so this transistor turns on the self latching pair. If SW3 is set as shown in the schema diagram, the lamp illuminates via SW2, which is normally closed; if set the other way, a square wave audio frequency generator formed by Q4, Q5 and related components is activated, driving the loudspeaker. If SW1 is left open, when mains supply is restored the lamp or the alarm continue to operate. They can be disabled by opening the main on-off switch SW2. If SW1 is closed, restoration of the mains supply terminates lamp or alarm operation, by applying a positive bias to the Base of Q2.
Notes: * Close SW2 after the schema is plugged. * Warning! The schema is connected to 230Vac mains, then some parts in the schema board are subjected to lethal potential!. Avoid touching the schema when plugged and enclose it in a plastic box.