SECTION 9.6 Millman's Theorem 26. Using Millman's theorem, find the current through and voltage across the resistor R, of Fig. 9.140. 27. Repeat Problem 26 for the network of Fig. 9.141. R₁1002 E₁40 V R₂ 60 E₂ 42 V FIG. 9.140 Problem 26. BL 30

Question is complete. Please solve asap Solve 26

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*23. Find the resistance R₁ of Fig. 9.137 such that the resistor R₂ will receive maximum power. Think! *24. a. For the network of Fig. 9.138, determine the value of R₂ for maximum power to R4 b. Is there a general statement that can be made about situations such as those presented here and in Prob- lem 23? *25. For the network of Fig. 9.139, determine the level of R that will ensure maximum power to the 100- resistor. E 100 V 4₁ = R₁100 E₂40 V R, Σ.200 Ω R₁ ww 25 0 SECTION 9.6 Millman's Theorem 26. Using Millman's theorem, find the current through and voltage across the resistor R, of Fig. 9.140. 27. Repeat Problem 26 for the network of Fig. 9.141. 110 mA R₂ FIG. 9.138 Problem 24. R₁2 kn R₂ ≥60 372 | NETWORK THEOREMS E₂42 V FIG. 9.140 Problem 26. R₁2000 + E, 400 V R3 w h 25 02 FIG. 9.142 Problem 28. R₁≤ R₁ +30 + E₂20 V R₂ 100 0 R₂ 8 mA tomno R₂ 6.8 ΚΩ www 4.70 1₂ 10 ΚΩ W R₂ E 10 V T4 mA R₂ 8.2 k 100 V 12 V R₁ rom = E, SV R₁2.2 kN 2.2 km WiFi 1₁ = 4 A R₁ W 4.7 Ω R₂ 500 FIG. 9.137 Problem 23. R₂ R₂ www 50 Ω FIG. 9.139 Problem 25. 500 Pot. 8.2 ΚΩ E₂* E₂20 V FIG. 9.141 Problem 27. R₂50 R₁100 28. Repeat Problem 26 for the network of Fig. 29. Using the dual of Millman's theorem, fin through and voltage across the resistor R₂ R₁ FIG. 9.143 Problem 29 = 1.6 A R₂ www 3.30 5.6 *30. Repeat Problem 29 for the network of Fig.