2 files changed, 48 insertions, 0 deletions

diff --git a/3554/CH10/EX10.1/Ex10_1.sce b/3554/CH10/EX10.1/Ex10_1.sce
new file mode 100644
index 000000000..1f381d119
--- /dev/null
+++ b/3554/CH10/EX10.1/Ex10_1.sce
@@ -0,0 +1,24 @@
+// Exa 10.1

+

+clc;

+clear all;

+

+// Given data

+

+// 1st measurement

+f1=1; //  in MHZ

+C1=500; // in pf

+// 2nd measurement

+f2=2; //in MHz

+C2=110; // in pf

+

+// Solution

+// Using equation 10.2(page no. 278) to calculate distributed Capacitance

+

+Cs=(C1-4*C2)/3; // Distributed capacitance in pf

+printf('The value of distributed capacitance = %d pf \n',Cs);

+// using equation of resonant frequency given as f1=1/(2*%pi*sqrt(L*(C1+Cs));

+// Therefore

+L=1/(4*(%pi)^2*f1^2*(C1+Cs)); // Inductor value

+

+printf(' The value of L(inductor) is =%.3f micro H \n',L*10^6); 

diff --git a/3554/CH10/EX10.2/Ex10_2.sce b/3554/CH10/EX10.2/Ex10_2.sce
new file mode 100644
index 000000000..227a1bcd5
--- /dev/null
+++ b/3554/CH10/EX10.2/Ex10_2.sce
@@ -0,0 +1,24 @@
+// Exa 10.2

+

+clc;

+clear all;

+

+// Given data

+

+f1=2; // in MHz

+f2=6; // in MHz

+C1=500; // in pf

+C2=50; // in pf

+

+// Solution

+

+disp("Given that f2=3*f1");

+disp("Therefore by using equation 10.1");

+disp(" 1/(2*%pi*sqrt(L*(C2+Cs)) = 3/(2*%pi*sqrt(L*(C1+Cs))");

+disp("Therefore");

+disp("C1+Cs=9(C2+Cs)");

+//Therefore Cs is given as

+Cs=(C1-9*C2)/8;// Self capacitance in pf

+printf(' \nThe value of the self capacitance is = %.2f pf \n', Cs);

+

+