(Solved): Consider the following figure. (1) (a) Find the equivalent resistance between points \( a \) and \( ...

Consider the following figure. (1) (a) Find the equivalent resistance between points \( a \) and \( b \) in the figure. \( (R=12.0 \Omega) \) \( \Omega \) (b) Calculate the current in each resistor if a potential difference of \( 56.0 \mathrm{~V} \) is applied between points \( a \) and \( b \). \( I(4.00= \) Use the potential difference between \( a \) and \( b \) and the equivalent resistance between \( a \) and \( b \) to fin \( \Omega) \) 2) = Use the poten \( I(7.00 \) \( \Omega) \)\( \quad X \) From the value of the current from a to \( b \) find the potential difference across the \( 7.00-\Omega \) resistor ar \( I(12.0= \) You appear to have used the current through the \( 4.00-\Omega \) resistor to calculate the current through t I) (incorrect, vour answer to this part of the problem is also incorrect.A \( I(9.00=1 \) \( \Omega) \) \( x \) the current through the \( 9.00-\Omega \) resistor is related to other currents you have calculate Consider the combination of resistors shown in the figure below. (a) Find the equivalent resistance between point \( a \) and \( b \). \( \Omega \) (b) If a voltage of \( 34.5 \mathrm{~V} \) is applied between points \( a \) and \( b \), find the current in each resistor. \( \begin{array}{ll}12 \Omega & \text { A } \\ 6 \Omega & \text { A } \\ 5 \Omega & \text { A } \\ 4 \Omega & \text { A } \\ 8 \Omega & \text { A }\end{array} \)