Showing posts with label test. Show all posts
Showing posts with label test. Show all posts
Thursday, September 18, 2014
Test Beeper For Your Stereo
The test beeper generates a sinusoidal signal with a frequency of 1,000 Hz, a common test frequency for audio amplifiers. It consists of a classical Wien-Bridge oscillator (also known as a Wien-Robinson oscillator). The network that determines the frequency consists here of a series connection of a resistor and capacitor (R1/C1) and a parallel connection (R2/C2), where the values of the resistors and capacitors are equal to each other. This network behaves, at the oscillator frequency (1 kHz in this case), as two pure resistors. The opamp (IC1) ensures that the attenuation of the network (3 times) is compensated for.
In principle a gain of 3 times should have been sufficient to sustain the oscillation, but that is in theory. Because of tolerances in the values, the amplification needs to be (automatically) adjusted. Instead of an intelligent amplitude controller we chose for a somewhat simpler solution. With P1, R3 and R4 you can adjust the gain to the point that oscillation takes place. The range of P1 (±10%) is large enough the cover the tolerance range. To sustain the oscillation, a gain of slightly more than 3 times is required, which would, however, cause the amplifier to clip (the ‘round-trip’ signal becomes increasingly larger, after all).
Circuit diagram:
To prevent this from happening, a resistor in series with two anti-parallel diodes (D1 and D2) are connected in parallel with the feedback (P1 and R3). If the voltage increases to the point that the threshold voltage of the diodes is exceeded, then these will slowly start to conduct. The consequence of this is that the total resistance of the feedback is reduced and with that also the amplitude of the signal. So D1 and D2 provide a stabilizing function. The distortion of this simple oscillator, after adjustment of P1 and an output voltage of 100 mV (P2 to maximum) is around 0,1%. You can adjust the amplitude of the output signal with P2 as required for the application. The circuit is powered from a 9-V battery. Because of the low current consumption of only 2 mA the circuit will provide many hours of service.
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In principle a gain of 3 times should have been sufficient to sustain the oscillation, but that is in theory. Because of tolerances in the values, the amplification needs to be (automatically) adjusted. Instead of an intelligent amplitude controller we chose for a somewhat simpler solution. With P1, R3 and R4 you can adjust the gain to the point that oscillation takes place. The range of P1 (±10%) is large enough the cover the tolerance range. To sustain the oscillation, a gain of slightly more than 3 times is required, which would, however, cause the amplifier to clip (the ‘round-trip’ signal becomes increasingly larger, after all).
Circuit diagram:
Test Beeper Circuit Diagram
To prevent this from happening, a resistor in series with two anti-parallel diodes (D1 and D2) are connected in parallel with the feedback (P1 and R3). If the voltage increases to the point that the threshold voltage of the diodes is exceeded, then these will slowly start to conduct. The consequence of this is that the total resistance of the feedback is reduced and with that also the amplitude of the signal. So D1 and D2 provide a stabilizing function. The distortion of this simple oscillator, after adjustment of P1 and an output voltage of 100 mV (P2 to maximum) is around 0,1%. You can adjust the amplitude of the output signal with P2 as required for the application. The circuit is powered from a 9-V battery. Because of the low current consumption of only 2 mA the circuit will provide many hours of service.
Author: Ton Giesberts - Copyright: Elektor Electronics 2007
Tuesday, September 9, 2014
Test Multiteste LEDs Polarity Continuity Resistance Circuit
What do you think of building a simple LED tester, so you can test the integrity of the components before soldering directly to the PCB. It reduces the task of testing the meter components using the schema with LED gives an indication about the good or bad condition of the component.
Test Multiteste LEDs - Polarity - Continuity - Resistance Circuit
When a component is placed in the schema and establishes electrical continuity T1 receives base current through R1. When T1 conducts, the green LED turns on and off the red LED. This indicates that the component to be tested is good. If the component is bad, will not have electrical continuity and T1 remains off. In this state only the red LED light indicating that the component is bad.
Polarity
Connect the red end of the positive range to the schema board and to test the black edge point. Circuit board under test to be lit
Green LED ON - positive feed. Green LED off and red LED - or no negative supply voltage.
Connect the red end of the positive range to the schema board and to test the black edge point. Circuit board under test to be lit
Green LED ON - positive feed. Green LED off and red LED - or no negative supply voltage.
Continuity
Connect both ends red and black throughout the test points
Green LED-Continuity. LED red if there is no continuity
Resistor. 1 ohm to 500K
Alloy ends red and black on each side of resistor
Green LED Resistor-OK. Green LED off and red LED Resistor burned
Connect both ends red and black throughout the test points
Green LED-Continuity. LED red if there is no continuity
Resistor. 1 ohm to 500K
Alloy ends red and black on each side of resistor
Green LED Resistor-OK. Green LED off and red LED Resistor burned
Electrolytic capacitor
Red probe tip to positive and black for negative capacitor.
Green LED turns on and off gradually and then red lights, Capacitor good. Red LED lights up steadily bad capacitor
LED diodes, photodiodes, infrared diodes
The Red pontaa probe anode and cathode Black
Green LED - LED Good and Green LED off and red LED diode, or LED bad
Change the direction of the tips. If the green LED diode or LED is open
LDR
Tips in red and black leads of the LDR
Under the light, green LED and red LED fading. covering the LDR with your hand. Green LED off LDR good
Red probe tip to positive and black for negative capacitor.
Green LED turns on and off gradually and then red lights, Capacitor good. Red LED lights up steadily bad capacitor
LED diodes, photodiodes, infrared diodes
The Red pontaa probe anode and cathode Black
Green LED - LED Good and Green LED off and red LED diode, or LED bad
Change the direction of the tips. If the green LED diode or LED is open
LDR
Tips in red and black leads of the LDR
Under the light, green LED and red LED fading. covering the LDR with your hand. Green LED off LDR good
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