2. (15 pts) An npn bipolar junction transistor is biased in the forward-active region. The common-base...
3. A silicon npn bipolar transistor is uniformly doped and biased in the forward active region with the base-collector junction reverse biased by 2.5 V. The metallurgical base width is 1.5 μm. The emitter, base collector doping concentrations are 5 × 1017, 1016, 2 × 1015 cm-3 respectively. a. At T-300 K, calculate the base-emitter voltage at which the minority carrier electron concentration at x-0 is 20% of the majority carrier hole concentration. At this voltage calculate the minority carrier...
Problem 2. A silicon NPN bipolar transistor has the following specifications: Emitter: N+: ND =1018 cm-3 , base: p-type, NA=1015 cm-3, collector: N-type, ND=5x1015 cm-3 . 1. Draw the energy band diagram of the transistor at thermal equilibrium, 2. If the transistor is biased at Normal Active Mode, emitter-base junction forward biased with 1 V, and collector-base junction is reverse biased with 4V, draw the energy band diagram.
d emier junction is forward biased and emitter-collector junction is reversed biased t. In cut oft mode junction is forward biased and emitter-collector junction is forward biased junction is reversed biased and emitter-collector junction is reversed biased junction is reversed biased and emitter-collector junction is forward biased is c) The base-emitter ) The to operate in active mode Collector-Base junction must be 7 For the BJT a) Heavily doped b) Must reversed bias c) Must be forward bias d) Lightly...
Consider a silicon device (which happens to be an npn bipolar transistor) with an emitter doping of 10^17/cm3, a base doping of 8x10^15/cm3 and a collector doping of 2x10^15/cm3. Carefully calculate how the band diagram, charge density, electric field and electrostatic potential as a function of distance for this device changes from the equilibrium case when this bipolar transistor is properly biased to work as an amplifier. In other words, show how the band diagram changes when the emitter-base junction...
8.3 Consider a conventional NPN BJT with uniform doping. The base-emitter junction is forward biased, and the base-collector junction is reverse biased. (a) Qualitatively sketch the energy band diagram. (b) Sketch the minority carrier concentrations in the base, emitter, and collector regions. (c) List all the causes contributing to the base and collector currents. You may neglect thermal recombination-generation currents in the depletion regions.
An NPN bipolar junction transistor (BJT) is used to turn on and off a 30 Ohm load using an Arduino digital output pin as shown. Assuming the transistor is on, in the saturation region, determine the power delivered to the 30 Ohm load. The voltage drop across the collector-emitter junction of the transistor is 0.2 Volts. +5 v 1308 ARDUINO SV UNO mne гоо са Vce=0.2 v Saturation VBE = 0.7V in active & Saturation regions
1. An npn transistor is operating in the forward-active region with a base current of 3 μA. It is found that IC = 225 μA for VCE = 5 V and IC = 265 μA for VCE = 10 V. What are the values of β and VA for this transistor
A uniformly doped silicon pnp transistor with base width of 2um is biased in forward active mode (with BC junction reverse biased). The doping concentrations are NE-1018cm NB-5x1016cm3, and Nc-1015cm3. Assume DB-25 cm2/s, TB-10-s and LB 16um (a) Calculate the values of no, рво, and nco. (b) For VEB 0.65V, determine the respective minority carrier concentration at the edge of the depletion layer, pa(0) and ne(0) (c) Sketch the minority carrier concentration through the device and label each curve (d)...
question 3 and 4 Problem2 (30 points) Consider an npn bipolar transistor with the following characteristics Base Collector Emitter Na-5x 1016 cm3 Ng- 1015 cm3 N1018 cm3 DC- 12 cm-/sec DE 8 cm-/sec (diff coef.) DB 15 cm-/sec sec TEO 108 sec (life time) tB0 5x 10 tCo 10 sec xp 0.7 um (Base width) xg 0.8 um (emitter width) D Remember D/u= KT /q, and L n.p n.p A forward bias of 0.5 V is applied to the emitter-base...
HELP with finding 8 and 9 2. IC temperature sensor The emitter-base voltage VEB of a PNP bipolar junction transistor (BJT) with its base and collector shorted (figure 1(a)) can be expressed by VEB (kT/q) In(Ic/Is), in which Is is the saturation current of the emitter-base junction (a) (3 pts) Choose any statement below that correctly describe the effect of temperature on the property of the BIT under a constant 1c as shown in figure 1(a).18_.(one or more than one...