Q: P. type semiconductor with length (I=5mm), the cross-section area of (A=0.5 mm^ 2 ). , and resistance (R = 250Omega) . Calculate the exact number of the majority (p p ) and the minority (n p ) carriers. Also, calculate the number of acceptor atoms (N A ) if the intrinsic carrier ( Pi j =2*10^ 20 /m^ 7 ) . Given the mobility for the electrons ( mu k =0.4m^ 2 /V.s) and for the holes ( mu 1 =0.2m^ 2 N.s) Note: use these equations to solve the problem. sigma tp = sigma e + sigma ll =n p e mu e +p p e ll n i ^ 2 =n p p p Compare your results if you use this equation instead for sigma tp with sigma tp = sigma p =p p e mu h 44 ll 6EP1 HW3.pdf →EE1- Electronic physic – HWW3Q: P. type semiconductor with length (= 5mm), the cross-section area of(A= 0.5 mm2), and resistance (R=2502). Calculate the exact number ofthe majority (Pp) and the minority (n,) carriers. Also, calculate the numberof acceptor atoms (NA) if the intrinsic carrier (n = 2x1020/m'). Given themobility for the electrons (u=0.4m2/V.s) and for the holes (u=0.2m2/V.s)Note: use these equations to solve the problem.Om = đe + ơh = npele + Ppeuhn = npPpCompare your results if you use this equation instead for om withOtp = Op = ppeuh 44 lllGoogle Lens W3.pdf->EE1- Electronic physic – HW3Q: P. type semiconductor with length (I= 5mm), the cross-section area of(A= 0.5 mm2), and resistance (R=2502). Calculate the exact number ofthe majority (Pp) and the minority (n,) carriers. Also, calculate the numberof acceptor atoms (NA) if the intrinsic carrier (n; = 2x1020/m"). Given themobility for the electrons (u-0.4m2/V.s) and for the holes (u=0.2m2/V.s)Note: use these equations to solve the problem.Otp = Ge + ơh = Npele + Ppelhn = npPpCompare your results if you use this equation instead for Gtp withOip = Op = Ppeµh:TP. type semiconductor with length (1 = 5ترجمة/ تعديل معادلة رياضيةر نسخ النصQ: P. type semiconductor with jc dylength (I = 5mm) , the cross-section area of%3Då 7A - 0 Em* m A 2

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Q: P. type semiconductor with length (= 5mm), the cross-section area of (A= 0.5 mm), and resistance (R=2502). Calculate the exact number of the majority (P,) and the minority (n,) carriers. Also, calculate the number of acceptor atoms (NA) if the intrinsic carrier (n; = 2x100/m). Given the mobility for the electrons (µ=0.4m?/V.s) and for the holes (u=0.2m2/V.s) Note: use these equations to solve the problem. Op = đe + ơh = npele + Ppeuh n = nạPp Compare your results if you use this equation instead for Otp with

Q: P. type semiconductor with length (= 5mm), the cross-section area of (A= 0.5 mm), and resistance (R=2502). Calculate the exact number of the majority (P,) and the minority (n,) carriers. Also, calculate the number of acceptor atoms (NA) if the intrinsic carrier (n; = 2x100/m). Given the mobility for the electrons (µ=0.4m?/V.s) and for the holes (u=0.2m2/V.s) Note: use these equations to solve the problem. Op = đe + ơh = npele + Ppeuh n = nạPp Compare your results if you use this equation instead for Otp with

Power System Analysis and Design (MindTap Course List)

6th Edition

ISBN:9781305632134

Author:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Publisher:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Chapter4: Transmission Line Parameters

Section: Chapter Questions

Problem 4.2P: The temperature dependence of resistance is also quantified by the relation R2=R1[ 1+(T2T1) ] where...

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