Armstrong oscillator
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The document describes the Armstrong oscillator, an electronic circuit that produces a sine wave output. It consists of an amplifier, tank circuit with inductor and capacitor, and a feedback path using a tickler coil. The oscillator works by using the amplifier to provide energy to the tank circuit on each cycle, which allows the oscillations to be sustained at a constant amplitude and frequency through regenerative feedback between the tank circuit and amplifier.
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The document describes the Colpitts oscillator circuit. It consists of an LC tank circuit made of capacitors and an inductor that produces sustained oscillations. The capacitors provide positive feedback to sustain oscillations at the resonant frequency of the tank circuit. It works by the energy transferring between the capacitors and inductor in the tank circuit. The Colpitts oscillator can generate high frequency sinusoidal waves and is commonly used as a local oscillator in radio receivers [END SUMMARY]
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However in certain sectors like banking sector, the size of book assets determine the value of the
company and not the earnings, hence in such situations we should consider Book value to Market
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Controlled Rectifier
The document discusses silicon controlled rectifiers (SCRs) and their applications:
1) SCRs can convert alternating current to direct current and control the amount of power fed to a load. They have applications in power control, switching, zero voltage switching, over-voltage protection, and pulse circuits.
2) SCRs are commonly used in circuits with two SCRs to control power to a resistive-inductive load by varying the conduction angle of the SCRs.
3) SCRs can be used to make and break AC circuits by applying trigger pulses to their gates through a control switch.
POWER SUPPLY(Ashu).pptx
The document discusses different components of a power supply including transformers, rectifiers, and filters. It provides details on half wave rectifiers, full wave rectifiers, and bridge rectifiers. It also describes different types of filters like capacitor filters and choke input filters that remove the AC component from rectified output. The key components of a regulated power supply are identified as the transformer, rectifier, filter, and voltage regulator.
AE UNIT II.ppt
This document discusses different types of rectifiers and filters used in analog electronics. It describes:
1) Half-wave and full-wave rectifiers, explaining how they work using diodes to convert AC to DC. Full-wave rectifiers provide higher output voltage and efficiency.
2) Capacitor input filters, which use a capacitor after the rectifier to filter ripple from the DC output. The capacitor charges during one half-cycle and discharges through the load during the other half-cycle.
3) Equations for calculating ripple factor and voltage. Larger capacitors and resistors reduce ripple. Capacitor filters are suitable for lighter loads due to poor regulation at higher currents.
Ijetr011823
ER Publication,
IJETR, IJMCTR,
Journals,
International Journals,
High Impact Journals,
Monthly Journal,
Good quality Journals,
Research,
Research Papers,
Research Article,
Free Journals, Open access Journals,
erpublication.org,
Engineering Journal,
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Thyristor commutation techniques
To turn on a Thyristor, there are various triggering methods in which a trigger pulse is applied at its Gate terminal. Similarly, there are various techniques to turn off a Thyristor, these techniques are called Thyristor Commutation Techniques.
Similar to Armstrong oscillator (20)
Several types of oscillators exist. In your own words, describeThe.pdf
Several types of oscillators exist. In your own words, describeThe.pdf
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game theory
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Elements
Non-zero-sum games
The Prisoner’s Dilemma
COOPERATIVE GAMES
BARGAINING GAMES
Why Should We Count This Point As A Solution?
Knowledge management factor and its impact on firm
The document discusses knowledge management (KM) effectiveness in the public sector of Islamabad. It aims to determine the relationship between leadership, culture, KM strategy, information technology, and firm performance on KM effectiveness. It presents hypotheses about the positive impacts of leadership, culture, KM strategy, and information technology on KM effectiveness. The study found a lack of KM strategy and leadership negatively impacted projects. It suggests KM effectiveness acts as a mediator to improve organizational performance. Future research should validate findings in other organizations and sectors.
Flouresence Spectroscopy
Two main types of instruments for fluorescence analysis are filter fluorimeters and spectrofluorometers. Filter fluorimeters use filters and monochromators to select excitation and emission wavelengths, while spectrofluorometers use a light source, filters or monochromators to select excitation wavelengths, and detectors to measure emission intensities of multiple wavelengths simultaneously. Lasers provide high intensity light at narrow wavelengths but have limited tunability, while other sources like mercury and xenon lamps have adjustable wavelengths but lower intensity. Monochromators are used to precisely select wavelengths but cannot block all stray light.
Argon and He-Cd Laser
The document discusses different types of ion lasers, focusing on argon lasers. It describes the construction of argon lasers, which consists of mirrors at each end, Brewster windows to reduce reflection loss, a high current power supply, and an argon gas laser tube cooled by water. Argon lasers produce multiple visible wavelengths when argon atoms are excited by an electric current. They require high voltages but can output high power. Applications include scientific research, medicine, and laser light shows.
FLOURESCENCE SPECTROSCOPY
Two main types of instruments for fluorescence analysis are filter fluorimeters and spectrofluorometers. Filter fluorimeters use filters and monochromators to select excitation and emission wavelengths, while spectrofluorometers use a light source, filters or monochromators to select excitation wavelengths, and detectors to measure emission intensities of multiple wavelengths simultaneously. Common light sources include lasers, mercury arc lamps, xenon arc lamps, and tungsten lamps.
Radio Frequency and Intermediate Frequency Amplifiers
Radio Frequency and Intermediate Frequency Amplifiers
RADIO FREQUENCY AMPLIFIERS
INTEMEDIATE FREQUENCY
IF AMPLIFIERS
Audio frequency amplifiers
Varactor Diode
The varactor diode is a semiconductor device that has a voltage-dependent variable capacitance. It consists of a standard PN junction with a depletion region that acts as a dielectric between the P and N regions, which form the capacitor plates. As the reverse bias voltage is increased, the depletion region width increases, reducing the capacitance according to the formula C∝1/√v. Varactor diodes are used in applications like voltage controlled oscillators, parametric amplifiers, and frequency multipliers that require a voltage-controlled variable capacitance.
Multistage amplifier 23
MULTISTAGE AMPLIFIERS
Definition: An amplifier formed by connecting several amplifiers in cascaded arrangement such that output of one amplifier becomes the input of other whose output becomes input of next and so on .
Each amplifier in this configuration is known as stage.
So several stages are connected to form multistage amplifier.
Working of multistage amplifier: Each amplifier connected perform the process of amplification
They convert their input signal into high amplified output signal.
Hence the output signal after passing through several amplifiers becomes highly amplified.
Each amplifier connected perform the process of amplification
They convert their input signal into high amplified output signal.
Hence the output signal after passing through several amplifiers becomes highly amplified.
Voltage gain: The overall voltage gain of multistage amplifier is product of voltage gain of individual amplifier.
If voltage is expressed in dB overall voltage gain is by the sum of voltage gain in dB of individual amplifier.
If we convert voltage gain into the db voltage gain then we use a relation.
Direct coupled multistage amplifier: A direct coupled amplifier is a type of amplifier in which two amplifier are connected in a such a way that one stage is coupled directly to the other without using any coupling or bypassing capacitor.
In this configuration dc collector voltage of first stage provides base bias to second stage means output of first stage becomes input of second stage.
Disadvantages : A small changes in the dc bias voltages due to temperature effects or power supply variation are amplified by the succeeding stages so an unwanted signal appears at the output.
Applicatons : It is used in TV receivers’ computers ,regulator circuits and other electronic instruments
Ebers moll model
Ebers Moll Model
h parameter
r parameter
z parameter
Forward Mode , Reverse Mode And Normal Mode Operation
Colpitts Oscillator
Electronic Oscillator ,classification ,linear and non linear ,circuit description , tank circuit ,working and operation , frequency of oscllation and Applications
Basics switching regulators
Definition, Operation , Working , Buck converter , Step up Configuration ,Step up Regulator Boost converter, Inverter configuration , Buck boost configuration ,Switch mode summary ,Advantages ,Disadvantages and Appplications
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Armstrong oscillator
- 2. Oscillator An electronic circuit that produces periodic oscillating electronic signal, i,e sine or cosine wave Converts Dc current from power supply to an Ac Current signal
- 3. Armstrong oscillator The ARMSTRONG OSCILLATOR is used to produce a sine-wave output of constant amplitude and of fairly constant frequency within the rf range The armstrong oscillator uses transformer coupling to feed back a portion of the amplifier output to the amplifier input Armstrong is also called tuned based oscillator
- 4. The major three components that form Armstrong oscillator A m p l i f i e r
- 5. Circuit Diagram for Armstrong Oscillator
- 6. Component Description In the circuit diagram, resistors R1 and R2 forms a voltage divider bias for the transistor Q1. Emitter resistor Re is meant for stabilizing the bias point. Ce is the emitter by-pass capacitor. Its job is to by-pass the amplified AC signals from dropping across Re. Cc is a DC blocking capacitor. Its job is to prevent DC currents from the tank circuit side from entering the base. Primary coil (L1) of the transformer and the capacitor C1 forms the tank circuit. L2 is a tickler coil,the feedback signal needed to produce oscillations is magnetically coupled into the tank inductor in the input circuit by a "tickler coil"
- 7. OPERATION OF ARMSTRONG When power supply is applied, the transistor Q1 starts conducting and its collector current starts to rise. From the circuit diagram, you can see that this collector current actually flows through secondary coil L2. This rise in current current through the secondary induces some voltage across the primary coil L1 by virtue of mutual induction. The secondary coil L2 is also called “Tickler Coil”. At this time, two actions occur. First, resonant tank capacitor C1 charges to this voltage; the tank circuit now has stored energy. Second, coupling capacitor C2 couples the positive signal to the base of Q1.
- 8. OPERATION… The process of coupling oscillations or signal to base As in the tank circuit there are countinous oscillations produced in such a way when capacitor is full charged it starts discharging through L1 and current through L1 starts increasing When capacitor is fully discharged there’s no emf left to maintain current through L1 so magnetic flux tends to collapse and coil L1 The coil L1 produces a back emf by virtue of self induction. This back emf charges the capacitor C1 again. Then the capacitor discharges through L1 and the cycle is repeated. The repetitive charging and discharging cycles result in a series of oscillations in the tank circuit.
- 9. With a positive signal on its base, Q1 conducts harder. With Q1 conducting harder, more current flows through L2, a larger voltage is induced into L1, and a larger positive signal is coupled back to the base of Q1 The transistor will continue to increase in conduction until it reaches saturation. At saturation, the collector current of Q1 is at a maximum value and cannot increase any further. With a steady current through L2, the magnetic fields are not moving and no voltage is induced into the tank circuit. With no external voltage applied, C1 acts as a voltage source and discharges. As the voltage across C1 decreases, its energy is transferred to the magnetic field of L1. OPERATION…
- 10. The coupling capacitor, Ce, has charged to approximately the same voltage as C1. As C1 discharges, Ce discharges. The primary discharge path for Ce is through R2 (shown by the dashed arrow). As C2 discharges, the voltage drop across R2 opposes the forward bias on Q1 and collector current begins to decrease. This is caused by the decreasing positive potential at the base of Q1. A decrease in collector current allows the magnetic field of L2 to collapse. The collapsing field of L2 induces a negative voltage into the secondary which is coupled through Ce and makes the base of Q1 more negative. This, again, is regenerative action; it continues until Q1 is driven into cutoff. When Q1 is cut off, the tank circuit continues to flywheel, or oscillate. The flywheel effect not only produces a sine-wave signal, but it aids in keeping Q1 cut off. Without feedback, the oscillations of L1 and C1 would dampen out after several OPERATION…
- 11. Summary of ARMSTRONG OSCILLATOR’s Operation The operation of the Armstrong oscillator is basically this: Power applied to the transistor allows energy to be applied to the tank circuit causing it to oscillate. Once every cycle, the transistor conducts for a short period of time (Class C operation) and returns enough energy to the tank to ensure a constant amplitude output signal.