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+{

+ "metadata": {

+  "name": "",

+  "signature": "sha256:5cdc0313c39e461d83bef4f404708f38e979d4c9312a95284be2bd9b855678fb"

+ },

+ "nbformat": 3,

+ "nbformat_minor": 0,

+ "worksheets": [

+  {

+   "cells": [

+    {

+     "cell_type": "heading",

+     "level": 1,

+     "metadata": {},

+     "source": [

+      "Chapter4-Electron Ballistics"

+     ]

+    },

+    {

+     "cell_type": "heading",

+     "level": 2,

+     "metadata": {},

+     "source": [

+      "Ex1-pg44"

+     ]

+    },

+    {

+     "cell_type": "code",

+     "collapsed": false,

+     "input": [

+      "\n",

+      "##Example 4.1\n",

+      "##Calculation of acceleration,time taken,distance covered and kinetic energy of an accelerating proton\n",

+      "\n",

+      "##given values\n",

+      "m=1.67  *10**-27;##mass of proton in kg\n",

+      "q=1.602 *10**-19;##charge of proton in Coulomb\n",

+      "v1=0;##initial velocity in m/s\n",

+      "v2=2.5*10**6;##final velocity in m/s\n",

+      "E=500.;##electric field strength in V/m\n",

+      "##calculation\n",

+      "a=E*q/m;##acceleration\n",

+      "print'%s %.1f %s'%('acceleration of proton in (m/s^2) is:',a,'');\n",

+      "t=v2/a;##time\n",

+      "print'%s %.5f %s'%('time(in s) taken by proton to reach the final velocity is:',t,'');\n",

+      "x=a*t**2./2.;##distance\n",

+      "print'%s %.1f %s'%('distance (in m)covered by proton in this time is:',x,'');\n",

+      "KE=E*q*x;##kinetic energy\n",

+      "print'%s %.3e %s'%('kinetic energy(in J) at the time is:',KE,'');\n",

+      "\n"

+     ],

+     "language": "python",

+     "metadata": {},

+     "outputs": [

+      {

+       "output_type": "stream",

+       "stream": "stdout",

+       "text": [

+        "acceleration of proton in (m/s^2) is: 47964071856.3 \n",

+        "time(in s) taken by proton to reach the final velocity is: 0.00005 \n",

+        "distance (in m)covered by proton in this time is: 65.2 \n",

+        "kinetic energy(in J) at the time is: 5.219e-15 \n"

+       ]

+      }

+     ],

+     "prompt_number": 1

+    },

+    {

+     "cell_type": "heading",

+     "level": 2,

+     "metadata": {},

+     "source": [

+      "Ex2-pg49"

+     ]

+    },

+    {

+     "cell_type": "code",

+     "collapsed": false,

+     "input": [

+      "import math\n",

+      "##Example 4.2\n",

+      "##electrostatic deflection\n",

+      "##given values\n",

+      "pi=3.141\n",

+      "V1=2000.;##in volts,potential difference through which electron beam is accelerated\n",

+      "l=.04;##length of rectangular plates\n",

+      "d=.015;##distance between plates\n",

+      "V=50.;##potential difference between plates\n",

+      "##calculations\n",

+      "alpha=math.atan(l*V/(2.*d*V1))*(180./pi);##in degrees\n",

+      "print'%s  %.1f %s'%('angle of deflection of electron beam is:',alpha,'')\n",

+      "v=5.93*(10**5)*math.sqrt(V1);##horizontal velocity in m/s\n",

+      "t=l/v;##in s\n",

+      "print'%s %.3e %s'%('transit time through electric field is:',t,'')"

+     ],

+     "language": "python",

+     "metadata": {},

+     "outputs": [

+      {

+       "output_type": "stream",

+       "stream": "stdout",

+       "text": [

+        "angle of deflection of electron beam is:  1.9 \n",

+        "transit time through electric field is: 1.508e-09 \n"

+       ]

+      }

+     ],

+     "prompt_number": 2

+    },

+    {

+     "cell_type": "heading",

+     "level": 2,

+     "metadata": {},

+     "source": [

+      "Ex3-pg50"

+     ]

+    },

+    {

+     "cell_type": "code",

+     "collapsed": false,

+     "input": [

+      "import math\n",

+      "##Example 4.3\n",

+      "##electron projected at an angle into a uniform electric field\n",

+      "##given values\n",

+      "v1=4.5*10**5;##initial speed in m/s\n",

+      "alpha=37*math.pi/180.;##angle of projection in degrees\n",

+      "E=200.;##electric field intensity in N/C\n",

+      "e=1.6*10**-19;##in C\n",

+      "m=9.1*10**-31;##in kg\n",

+      "a=e*E/m;##acceleration in m/s**2\n",

+      "t=2*v1*math.sin(alpha)/a;##time in s\n",

+      "print'%s %.2e %s'%('time taken by electron to return to its initial level is:',t,'')\n",

+      "H=(v1**2.*math.sin(alpha)*math.sin(alpha))/(2.*a);##height in m\n",

+      "print'%s %.4f %s'%('maximum height reached by electron is:',H,'')\n",

+      "s=(v1**2.)*(2.*math.sin(alpha)*math.cos(alpha))/(2.*a);##print'%s %.1f %s'%lacement in m\n",

+      "print'%s %.4f %s'%('horizontal displacement(in m)when it reaches maximum height is:',s,'')"

+     ],

+     "language": "python",

+     "metadata": {},

+     "outputs": [

+      {

+       "output_type": "stream",

+       "stream": "stdout",

+       "text": [

+        "time taken by electron to return to its initial level is: 1.54e-08 \n",

+        "maximum height reached by electron is: 0.0010 \n",

+        "horizontal displacement(in m)when it reaches maximum height is: 0.0028 \n"

+       ]

+      }

+     ],

+     "prompt_number": 3

+    },

+    {

+     "cell_type": "heading",

+     "level": 2,

+     "metadata": {},

+     "source": [

+      "Ex4-pg53"

+     ]

+    },

+    {

+     "cell_type": "code",

+     "collapsed": false,

+     "input": [

+      "import math\n",

+      "##Example 4.4\n",

+      "##motion of an electron in a uniform magnetic field\n",

+      "##given values\n",

+      "V=200.;##potential difference through which electron is accelerated in volts\n",

+      "B=0.01;##magnetic field in wb/m**2\n",

+      "e=1.6*10**-19;##in C\n",

+      "m=9.1*10**-31;##in kg\n",

+      "v=math.sqrt(2.*e*V/m);##electron velocity in m/s\n",

+      "print'%s %.1f %s'%('electron velocity is:',v,'')\n",

+      "r=m*v/(e*B);##in m\n",

+      "print'%s %.4f %s'%('radius of path (in m)is:',r,'')"

+     ],

+     "language": "python",

+     "metadata": {},

+     "outputs": [

+      {

+       "output_type": "stream",

+       "stream": "stdout",

+       "text": [

+        "electron velocity is: 8386278.7 \n",

+        "radius of path (in m)is: 0.0048 \n"

+       ]

+      }

+     ],

+     "prompt_number": 4

+    },

+    {

+     "cell_type": "heading",

+     "level": 2,

+     "metadata": {},

+     "source": [

+      "Ex5-pg54"

+     ]

+    },

+    {

+     "cell_type": "code",

+     "collapsed": false,

+     "input": [

+      "import math\n",

+      "##Example 4.5\n",

+      "##motion of an electron in a uniform magnetic field acting at an angle\n",

+      "##given values\n",

+      "v=3*10**7;##electron speed\n",

+      "B=.23;##magnetic field in wb/m**2\n",

+      "q=45*math.pi/180;##in degrees,angle in which electron enter field\n",

+      "e=1.6*10**-19;##in C\n",

+      "m=9.1*10**-31;##in kg\n",

+      "R=m*v*math.sin(q)/(e*B);##in m\n",

+      "print'%s %.5f %s'%('radius of helical path is:',R,'')\n",

+      "p=2*math.pi*m*v*math.cos(q)/(e*B);##in m\n",

+      "print'%s %.4f %s'%('pitch of helical path(in m) is:',p,'')"

+     ],

+     "language": "python",

+     "metadata": {},

+     "outputs": [

+      {

+       "output_type": "stream",

+       "stream": "stdout",

+       "text": [

+        "radius of helical path is: 0.00052 \n",

+        "pitch of helical path(in m) is: 0.0033 \n"

+       ]

+      }

+     ],

+     "prompt_number": 5

+    },

+    {

+     "cell_type": "heading",

+     "level": 2,

+     "metadata": {},

+     "source": [

+      "Ex6-pg55"

+     ]

+    },

+    {

+     "cell_type": "code",

+     "collapsed": false,

+     "input": [

+      "import math\n",

+      "##Example 4.6\n",

+      "##Magnetostatic deflection\n",

+      "##given values\n",

+      "D=.03;##deflection in m\n",

+      "m=9.1*10**-31;##in kg\n",

+      "e=1.6*10**-19;##in C\n",

+      "L=.15;##distance between CRT and anode in m\n",

+      "l=L/2.;\n",

+      "V=2000.;##in voltsin wb/\n",

+      "B=D*math.sqrt(2.*m*V)/(L*l*math.sqrt(e));##in wb/m**2\n",

+      "print'%s %.4f %s'%('transverse magnetic field acting (in wb/m^2)is:',B,'')\n"

+     ],

+     "language": "python",

+     "metadata": {},

+     "outputs": [

+      {

+       "output_type": "stream",

+       "stream": "stdout",

+       "text": [

+        "transverse magnetic field acting (in wb/m^2)is: 0.0004 \n"

+       ]

+      }

+     ],

+     "prompt_number": 2

+    },

+    {

+     "cell_type": "heading",

+     "level": 2,

+     "metadata": {},

+     "source": [

+      "Ex7-pg57"

+     ]

+    },

+    {

+     "cell_type": "code",

+     "collapsed": false,

+     "input": [

+      "import math\n",

+      "##Example 4.7\n",

+      "##electric and magnetic fields in crossed configuration\n",

+      "##given values\n",

+      "B=2*10**-3;##magnetic field in wb/m**2\n",

+      "E=3.4*10**4;##electric field in V/m\n",

+      "m=9.1*10**-31;##in kg\n",

+      "e=1.6*10**-19;##in C\n",

+      "v=E/B;##in m/s\n",

+      "print'%s %.1f %s'%('electron speed is:',v,'')\n",

+      "R=m*v/(e*B);##in m\n",

+      "print'%s %.3f %s'%('radius of circular path (in m) when electric field is switched off',R,'')"

+     ],

+     "language": "python",

+     "metadata": {},

+     "outputs": [

+      {

+       "output_type": "stream",

+       "stream": "stdout",

+       "text": [

+        "electron speed is: 17000000.0 \n",

+        "radius of circular path (in m) when electric field is switched off 0.048 \n"

+       ]

+      }

+     ],

+     "prompt_number": 7

+    }

+   ],

+   "metadata": {}

+  }

+ ]

+}
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