Here You will know only about the subject of Electronic Device And Circuit Theory ( ELECTRONICS 1)
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Tuesday, December 9, 2008
Definition of Bipolar Junction Transistor (BJT)
Regions of BJT Operation
Cut-off region: -
The transistor is off. There is no conduction between the collector and the emitter.
Active region: -
The transistor is on. The collector current is proportional to and controlled by the base current (Ic=ßIB) and relatively insensitive to VCE. In this region the transistor can be an amplifier.
Saturation region: -
Rules for Bipolar Junction Transistors (BJTS)
Saturday, December 6, 2008
Basic Equations For The BJT
For pnp: VBE – 0.6 V
For both npn and pnp anytime
IE = IC + IB
For both npn and pnp only in the active region
IC = h FE IB = ß IB
IE = IC+ IB = (ß+1) IB ~ ß IB
Common Circuit Application(Source Follower)
The simple source follower is shown below. The improved version is shown at the right. The lower JFET forms a current source. The result is that VGS is held constant, removing the defects of the simple circuit.
Common Circuit Application(Current source)
Common Circuit Application(Voltage Controlled Switch)
For the on state the gate voltage VGS = 0 and for the off state |VGS| > |VGS.off| (of greater magnitude then VGS.off and with the same sign). The sign of the voltage depends on the type of FET, negative for n-channel and positive for p-channel.
Tuesday, December 2, 2008
Regions of JFET operation
Cut-off Region: -
The transistor is off. There is no conduction between the drain and the source when the gate-source voltage is greater than the cut-off voltage (ID = 0 for VGS > VGSoff)
The transistor is on. The drain current is controlled by the gate-source voltage (VGS) and relatively insensitive to VDS. In this region the transistor can be an amplifier.
The transistor is on, but behaves as a voltage proportional to the source-drain voltage and is controlled by the gate voltage.
ID = IDSS [ 2 (1 – VGS / VGSoff) VDS / - VGSoff - (VDS / VGSoff) 2 ]
In the Ohmic Region: RDS ≈ VGSoff / 2IDSS (VGS - VGSoff) = 1 / gm
Definition of Field effect Transistor (FET) and FET Schematic Symbols
The FET is a three terminal device like the BJT, but operates by a different principle. The three terminals are called the source, drain and gate. The voltage applied to the gate controls the current flowing in the source-drain channel. Because no current flows through the gate, the input impedance of the FET is extremely large (in the range of 1010 - 1015 Ω). The large input impedance of the FET makes them an excellent choice for amplifier inputs.
The two common families of FETs, the junction FET (JFET) and the metal oxide semiconductor FET (MOSFET) differ in the way the gate contact is made on the source-drain channel.
FET Schematic Symbols: -
Two Versions of the symbols are in common use. The symbols in the top row depict the source and drain as being symmetric. This is not generally true. Slight asymmetries are built into the channel during manufacturing which optimize the performance of the FET. Thus it is necessary to distinguish the source from the drain. In this class we will use the asymmetric symbols found on the bottom row, which depict the gate nearly opposite the source. The designation n-channel means that the channel is n doped and the gate is p doped. The p-channel is complement of n-channel.
Sunday, November 9, 2008
Output Impedance of a Transistor for the Emitter Follower (Common Collector)
Zout = - dVout / dIout
The minus sign in the derivative comes from the fact the output impedance has the effect of decreasing Vout. The output current IE, which is related to the base current.
Vin = IBRS + VBE +VE [Vout = VE]
Vout = VE = Vin – IBRS – VBE [Iout = IE and IB = IE/(β + 1)]
Vout = Vin – {IE/(β + 1)}RS – VBE = Vin – {Iout/( β + 1)}RS – VBE
= - Iout{RS/(β + 1)} + (Vin – VBE)
So, Zout = - dVout/dIout = -d/dIout [ - Iout{RS/(β + 1)} + (Vin – VBE) ]
Zout = RS/(β + 1)
Thus we obtain the result that the impedance of the source, as viewed by the load, is reduced by the factor ~ 1/ β.
Zout = {RS/( β + 1) ≈ RS/β |
Saturday, November 8, 2008
Input Impedance of a Transistor
We can easily find Zin from what we know already of the behavior of the transistor. We know that the sum of VBE and the IR drop across RE must equal Vin.
Vin = VB = VBE +VE = VBE + IERE [IR = IC + IB = βIB + IB = (β + 1)IB]
Vin =VBE + IERE = IB(β + 1)RE [IB = Iin]
Vin = VBE + Iin (β + 1) RE
Taking the derivative of Vin with respect to Iin, remembering that VBE is a constant, we get the result:
Zin = dVin/dIin = d/dIin(VBE + Iin (β + 1)RE) = (β + 1)RE
Zin = (β + 1)RE ≈ βRE |
Because IE = IB (β + 1). The IR drop across RE is greater then it would be for IB alone. The amplification of the base current causes RE to appear larger to a source looking into the input by (β + 1).
Definition of Gain
Gain is defined as the ratio of the output signal to the input signal. Because transistor amplifiers often have a quiescent output (a non zero output when the input is zero) we define gain as the derivative of the output with respect to the input. Thus gain is defined as the ratio of the change in output to the change in input.
Note that a negative gain means that the sign of the signal is inverted. Negative gain is not possible for Power Gain. |A| less than unity indicate that the output is smaller than the input.
Types of Amplifiers
The transistor is a three terminal device, thus the input and the output must share one terminal in collector, common emitter, and common base.
Friday, November 7, 2008
Ohmmeters view of the BJT
Wednesday, November 5, 2008
Common Circuit Application(JFET Diode)
The JFET pn gate junction can be used as a diode by connecting the source and the drain terminals. This is done if very low reverse leakage currents are required. The leakage current is very low because the reverse leakage current scales with the gate area. Small gate areas are designed into JFETs because it decreases the gate-source and the gate-drain capacitances.
Metal–oxide–semiconductor Structure
When a voltage is applied across a MOS structure, it modifies the distribution of charges in the semiconductor. If we consider a P-type semiconductor (with NA the density of acceptors, p the density of holes; p = NA in neutral bulk), a positive voltage, VGB, from gate to body (see figure) creates a depletion layer by forcing the positively charged holes away from the gate-insulator/semiconductor interface, leaving exposed a carrier-free region of immobile, negatively charged acceptor ions. See doping (semiconductor). If VGB is high enough, a high concentration of negative charge carriers forms in an inversion layer located in a thin layer next to the interface between the semiconductor and the insulator. (Unlike the MOSFET, discussed below, where the inversion layer electrons are supplied rapidly from the source/drain electrodes, in the MOS capacitor they are produced much more slowly by thermal generation through carrier generation and recombination centers in the depletion region.) Conventionally, the gate voltage at which the volume density of electrons in the inversion layer is the same as the volume density of holes in the body is called the threshold voltage.
This structure with P-type body is the basis of the N-type MOSFET, which requires the addition of an N-type source and drain regions.
From: - Wikipedia Encyclopedia
NMOS logic
NMOS logic uses n-type metal-oxide-semiconductor field effect transistors (MOSFETs) to implement logic gates and other digital circuits. nMOS transistors have three modes of operation: cut-off, triode, and saturation (sometimes called active).
The n-type MOSFETs are arranged in a so-called "pull-down network" (PDN) between the logic gate output and negative supply voltage, while a resistor is placed between the logic gate output and the positive supply voltage. The circuit is designed such that if the desired output is low, then the PDN will be active, creating a current path between the negative supply and the output.
A | B | A NOR B |
---|---|---|
0 | 0 | 1 |
0 | 1 | 0 |
1 | 0 | 0 |
1 | 1 | 0 |
While NMOS logic is easy to design and manufacture (a MOSFET can be made to operate as a resistor, so the whole circuit can be made with NMOSFETs), it has several shortcomings as well. The worst problem is that a DC current flows through an NMOS logic gate when the PDN is active, that is whenever the output is low. This leads to static power dissipation even when the circuit sits idle.
Also, NMOS circuits are slow to transition from low to high. When transitioning from high to low, the transistors provide low resistance, and the capacitative charge at the output drains away very quickly. But the resistance between the output and the positive supply rail is much greater, so the low to high transition takes longer. Using a resistor of lower value will speed up the process but also increases static power dissipation.
PMOS logic
pMOS logic uses p-type metal-oxide-semiconductor field effect transistors (MOSFETs) to implement logic gates and other digital circuits. pMOS transistors have three modes of operation: cut-off, triode, and saturation (sometimes called active).
The p-type MOSFETs are arranged in a so-called "pull-up network" (PUN) between the logic gate output and positive supply voltage, while a resistor is placed between the logic gate output and the negative supply voltage. The circuit is designed such that if the desired output is high, then the PUN will be active, creating a current path between the positive supply and the output.
While pMOS logic is easy to design and manufacture (a MOSFET can be made to operate as a resistor, so the whole circuit can be made with pMOSFETs), it has several shortcomings as well. The worst problem is that a DC current flows through a pMOS logic gate when the PUN is active, that is whenever the output is high. This leads to static power dissipation even when the circuit sits idle.
Also, pMOS circuits are slow to transition from high to low. When transitioning from low to high, the transistors provide low resistance, and the capacitative charge at the output drains away very quickly. But the resistance between the output and the negative supply rail is much greater, so the high to low transition takes longer. Using a resistor of lower value will speed up the process but also increases static power dissipation.
From: - Wikipedia encyclopedia