ERRATA for RF and Microwave Design: A Systems Approach, Second Edition, First Printing by Michael Steer, 2013.

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ERRATA fr RF and Micrwave Design: A Systems Apprach, Secnd Editin, First Printing by Michael Steer, 2013.

1 ERRATA fr RF and Micrwave Design: A Systems Apprach, Secnd Editin, First Printing by Michael Steer, Pages with crrectins: 2, 4, 31, 36, 37, 46, 49, 50, 73, 94, 95, 96, 126, 147, 153, 154, 195, 196, 207, 237, 256, 279, 293, 295, 296, 302, 303, 317, 337, 347, 398, 399, 400, 428, 430, 453, 495, 524, 537, 550, 609, 626, 627, 631, 635, 643, 653, 666, 682, 686, 767, 838, 859, 860, 872, 916, 981, 1028, 1056, 1127, 1128 (55 pages) Recent Crrectins Oct. 16, 2016 Page 398, Equatin (8.180), Replace ( )/( ) = by (40 45)/(40+45) = Oct. 16, 2016 Page 398, Replace Equatin (8.180) by R Lc = V c/i c = ½(V 1 + V 2)/ I c = ¼(R 1 + R 2) = 40 Ω. Oct. 16, 2016 Page 398, Replace equatin befre Equatin (8.180) by V 1 = ½I cr 1, V 2 = ½I cr 2 Oct. 16, 2016 Page 398, Part (c), Line 4, Change vltage, V c, applied acrss t current, I c, t Oct. 16, 2016 Page 398. Figure 8-30(d). Change tp V c t V 1. Change bttm V c t V 2. Oct. 16, 2016 Page 399, Delete Example 8.9 Sep. 29, 2016 Page 347, Exercise 7.4, Last line, Change 70 t 240 Sep. 16, 2016 Page 207, Example 5.2, Line 2, Delete and the wavelength is 40 cm Sep. 16, 2016 Page 237, Equatin abve (5.122), Change 8.78 ma t 5.48 ma Sep. 16, 2016 Page 237, Equatin abve (5.122), Change t Aug. 19, 2016 Page 1127, Fr 1.4(b), Change fj t J Aug. 18, 2016 Page 1127, Fr 1.7, Change 3.25 t 3.75 Apr. 1, 2016 Page 303, Line fllwing Slutin: Change w = s t w = 500 µm, s Apr. 1, 2016 Page 303, Equatin (6.63), change t Apr. 1, 2016 Page 303, Equatin (6.64), change 94.5 t 45.1 Mar. 29, k / 1+ k Page 302, Equatin (6.60), Change π ln 2 t π ln k / 1 k

2 Jan. 28, 2016 Page 653, Add fllwing Equatin (14.7) when the available signal and image pwers at the input are the same. Errata By Page Number 2 Last line f ftnte f Table 1-1. Change EHz = Hz t EHz = Hz 4 Table 1-2, Line UHF, Clumn 3 wavelength, Change 10 1 t Secnd line befre Equatin (2.1). Change RF t IF 36 Equatin (2.4). Change xt () t x 2 () t 37 Example 2.1, 4 th line f the slutin. Change x rms = = t ( ) x = + = and s rms rms x = 46 Example 2.4, Equatin (2.36), change 0.5 t Example 2.5, last line n page. Change t 2 50 Equatin (2.40), Change PMEPR t PAPR 73 Table 2-4, Entry fr 32-QAM (ideal), Change 4 t 5 I 1 I I 1 = I 79 Example 2.10, line 7, Change = ( ) t ( ) ; Exercise 1. Change PAR t PMEPR 95 Exercise 9, line 1. Change FM t PM 95 Exercise 13. Change xt () t yt () in parts (a) and (d) 96 Exercise 2.14(a), change PAR t PAPR 96 Exercise 2.14(b), change PAR t PAPR 126 Equatins (3.33) and (3.35), Change L LINK,LOS t L PATH,LOS 147 Sectin 4.2.3, line 10, change n receive channel t ne receive channel 153 Example 4.1, equatin shuld be Bm 10 MHz GP = = = 10 = 10 db B 1 MHz b 154 Equatin (4.5), change db = db t 10 db = 13 db 195 Exercise 17. Add t the end f (b). (Use a mdulatin efficiency f 2 b/s/hz.) 195 Exercise 18, line 3. Delete f 10 kbps 195 Exercise 18, last line. Change supprted? t supprted using ideal BPSK? 196 Prblem 22(c). Change 16 t 48 (twice) 196 Prblem 22(e). Change 2.7 t Example 5.2, Line 2, Delete and the wavelength is 40 cm 237 Equatin abve (5.122), Change 8.78 ma t 5.48 ma 237 Equatin abve (5.122), Change t End f first paragraph. Delete The quarter-wave transfrmer is als called an impedance inverter (r equivalently an admittance inverter). 256 Equatin (5.197). Change P t T 2 P T1 256 Equatin (5.195). Change P t T 2 P T1 279 Sectin 6.4.1, Line 11, Change mm t cm 293 Equatin (6.26) Change q = t q = Line fllwing (6.36), Change < (63 t > ( Line fllwing (6.38), Change > t <

3 296 Example 6.3, Slutin (a), line 3, Change (44 ε r ) [= (44 5.6)=38.4] t (44 2ε r ) [= ( )=32.8] 302 Equatin (6.58), Change ε eff t ε e k / 1+ k Equatin (6.60), Change π ln 2 t π ln k / 1 k 303 Equatin (6.64), Change ε eff t ε e 303 Line fllwing Slutin: Change w = s t w = 500 µm, s 303 Equatin (6.63), change t Equatin (6.64), change 94.5 t Sectin 7.2.4, Secnd paragraph, Line 1, Change δ t δ s 324 Captin f Figure 7-11, Line 9, Change 70 t Captin f Figure 7-12, Line 8, Change 240 t line befre Equatin (7.35), Change transient t transverse 347 Exercise 7.4, Last line, Change 70 t Exercise 6(a). Change `magnetic t micrstrip 358 Equatin (8.9), change (V 1 + V 2) t (V 1 - V 2) 398 Equatin (8.180), Replace ( )/( ) = by (40 45)/(40+45) = Replace Equatin (8.180) by R Lc = V c/i c = ½(V 1 + V 2)/ I c = ¼(R 1 + R 2) = 40 Ω. 398 Replace equatin befre Equatin (8.180) by V 1 = ½I cr 1, V 2 = ½I cr Part (c), Line 4, Change vltage, V c, applied acrss t current, I c, t 398 Figure 8-30(d). Change tp V c t V 1. Change bttm V c t V Equatin (8.182), change bttm R Lc Z 0e t R Lc + Z 0e 399 Equatin (8.185), change bttm R Ld Z 0d t R Ld + Z 0d 399 Delete Example Line fllwing (d), change even t dd 428 Equatin (9.113), Change a t 1 a,change Example 9.3, Equatin (9.128). Change t Example 9.3, Equatin (9.128). Lines 1, 2 and 3. Add expnent f 1 t secnd matrix. 430 Example 9.3, Equatin (9.128). Last line, Change t (twice) 453 Figure 10-6(a), Change lwer left 1 t S Figure 10-6(b), Change 1 t S Equatin (10.9), Change b 2 = S 21a 1 + a 3 t b 2 = S 21a 1 + S 23a Equatin (10.10), Change (1 S 32)b 3 = s 32 S 21a 1 t (1 S 23 S 32)b 3 = S 32 S 21a Equatin (10.11), Change 1 S 32 t 1 S 23S Exercise 25, Line 2, Change 0.7, S 21 t 0.7, S Sectin 11.7, Line 3, Change (se and f) t (e and f) 537 Example 11.3, Slutin, line 3, Change t Change ph t nh (twice). Change ff t ff (twice). Change ff t ff.

4 550 Exercise 11.18(b), line 3, change many windings are n the unbalanced t change many windings are n the balanced 609 kt Equatin (13.17) Change e hf kt t hf 1 hf ( kt ) e Line 3 after Equatin (13.17), Change f c = kt t fc = 2kT 609 Line 4 after Equatin (13.17) Change 6 t Equatin (13.77), Change N dbm,i ) SNR db,min t N dbm,i SNR db,min) 627 Equatin (13.78), Change N dbm, ) SNRMIN t N dbm, SNR db,min) 631 Figure 13-21(c), In captin change `Switch n mdel t `Ideal switch n mdel 631 Figure 13-21(d), In captin change `Swtch ff mdel t `Realistic switch n mdel 635 Equatin (13.88), Change t Questin 7(a), line 3, Change 270 t Questin 7(a), line 3, Delete (270 K) 653 Add fllwing Equatin (14.7) when the available signal and image pwers at the input are the same. 666 last line, Change dbc t dbm 682 Equatin (14.43), Change mw = 16.0 dbm t mw = 11.8 dbm 682 Equatin (14.44), Change 70.7 mw = 18.5 dbm t 25 mw = 14.0 dbm 686 Example 14.3, Line 3, Change OIP3 2 = 50 t OIP3 2 = Exercise 8, last line, Change Table t Figure 818 Captin f Figure 17-1, line 1, Change pnp t npn * 838 Paragraph 2, Line 6, Delete (since S = S usually) Paragraph 2, Line 4, change utput t input 860 Equatin (17.105), Change G =ΓΓ t 1 2 G = Γ1Γ Figure 17-24(a). The right-directed arrw ging int the summing junctin shuld have a + sign next t it; the upwards-directed arrw ging int the summing junctin shuld have a - sign next t it. 872 Exercise 7. Line 4, Change t Exercise 8. Line 4, Change t Exercise 21(c) line 3, Change dd-mde lad resistance RL t even-mde lad resistance RLe 916 Exercise 21(d) lines 3,4, Change cmmn-mde lad resistance RLc t differentialmde lad resistance RLd 981 Figure 20-12, Fr TL1 change Z 0 = 50 Ω t Z 0 = 70 Ω (twice) 1023 Exercise 13. Line 7 change f scillatr? t f the scillatr? 1023 Exercise 14. Line 7 change f scillatr? t f the scillatr? 1028 Equatin (A.18), Change cs y t cs x 1050 Table B-1. Line 4 in table fr F, Change A 2 t A Line fr Slder > tin-lead, change 17.2 t Fr 1.4(b), Change fj t J 1127 Fr 1.7, Change 3.25 t Fr 6.18(b), Change t r 10.89

5 1127 Fr 6.5, Change t Fr 9.6(d), Change 50 + ȷ100 Ω t ȷ Answer t 11.16, Change L = 10.3 nh t L = 20.7 nh 1128 Answer t 17.1, Change 1 db t 21 db 1128 Clumn 3, Slutin t 17.24, secnd last line, Change L3 t L4, Change C4 t C5

6 CLARIFICATIONS The fllwing are nt errata but prvide clarificatin. 36 Third line frm the bttm f the page. Change The CF is a vltage rati and has the same meaning as PAR t The CF is a vltage rati and smetimes has the same meaning as PAR 42 Paragraph 1, Line 5. Change P p. Then t P p (this is nt the same as P p in Equatin (2.5)). Then 435 Line befre Equatin (9.158). Change Since t Since (with the same real reference impedance) 451 At the end f the captin fr Figure 10-2 add (The same real reference impedance must be used at each prt.) 503 Exercise 22, Line 6, Change and an element t and then an element 798 Add t captin f Figure (Derived using R L = 50 Ω and K = Ω.)

Three charges, all with a charge of 10 C are situated as shown (each grid line is separated by 1 meter).

Three charges, all with a charge f 0 are situated as shwn (each grid line is separated by meter). ) What is the net wrk needed t assemble this charge distributin? a) +0.5 J b) +0.8 J c) 0 J d) -0.8 J e)