Question
please send it in good quality so that i can read it i am sending this second time because i couldnt read the answer in
please send it in good quality so that i can read it i am sending this second time because i couldnt read the answer in first one
write a code in fortrun software ( that works in fortrun and also uses the paper in the picture ) and design an microstrip rectangular antenna . Antenna should work in 9.40 GHz and with the code that you write we should get radiation diagrams , HPBW , F/B ratio , gain parameters from the code . ( the questatio. is based on antenna theory book author is balannis and part 14 )
what kind of information do you need there is no more information about the questation use microstrip antenna formulas and calculate an antenna that works at 9.40 GHz in fortrun software ( write in fortrun language )
your comments are really hard to understand i need more information about what kind of information you need
COMPUTER PROGRAM - MICROSTRIP ANTENNAS THIS IS A FORTRAN PROGRAM THAT DESIGNS AND COMPUTES THE ANTENNA RADIATION CHARACTERISTICS OF: I. RECTANGULAR II. CIRCULAR MICROSTRIP PATCH ANTENNAS BASED ON THE CAVITY MODEL AND DOMINANT MODE OPERATION FOR EACH. THAT IS: A. TM10 MODE FOR THE RECTANGULAR PATCH B. TM110 MODE FOR THE CIRCULAR PATCH nnnnnnnnnnnnnnn0000000000000000000000 **INPUT PARAMETERS 1. FREQ = RESONANT FREQUENCY , (in GHz) 2. EPSR = DIELECTRIC CONSTANT OF THE SUBSTRATE & 3. HEIGHT = HEIGHT OF THE SUBSTRATE h (in cm) 4. YO = POSITION OF RECESSED FEED POINT Y. (in cm) RELATIVE TO LEADING RADIATING EDGE OF RECTANGULAR PATCH. NOT NECESSARY FOR CIRCULAR PATCH **OUTPUT PARAMETERS A. RECTANGULAR PATCH: 1. PHYSICAL WIDTH OF PATCH W (in cm) 2. EFFECTIVE LENGTH OF PATCH Le (in cm) 3. PHYSICAL LENGTH OF PATCH L (in cm) 4. NORMALIZED E-PLANE AMPLITUDE PATTERN (in dB) 5. NORMALIZED H-PLANE AMPLITUDE PATTERN (in dB) 6. E-PLANE HALF-POWER BEAMWIDTH (in degrees) 7. H-PLANE HALF-POWER BEAMWIDTH (in degrees) 8. DIRECTIVITY (dimensionless and in dB) 9. RESONANT INPUT RESISTANCE (in ohms) a. AT LEADING RADIATING EDGE (y=0) b. AT RECESSED FEED POINT FROM LEADING RADIATING EDGE (y = yo) B. CIRCULAR PATCH: 1. PHYSICAL RADIUS OF THE PATCH a (in cm) 2. EFFECTIVE RADIUS OF THE PATCH (in cm) 3. NORMALIZED E-PLANE AMPLITUDE PATTERN (in dB) 4. NORMALIZED H-PLANE AMPLITUDE PATTERN (in dB) 5. E-PLANE HALF-POWER BEAMWIDTH (in degrees) 6. H-PLANE HALF-POWER BEAMWIDTH (in degrees) 7. DIRECTIVITY (dimensionless and in dB) Write a Fortran code for rectangular microstrip antenna that works at 9.40 GHz to find ;radiation diagrams, HPBW, F/B ratio, gain parameters. COMPUTER PROGRAM - MICROSTRIP ANTENNAS THIS IS A FORTRAN PROGRAM THAT DESIGNS AND COMPUTES THE ANTENNA RADIATION CHARACTERISTICS OF: I. RECTANGULAR II. CIRCULAR MICROSTRIP PATCH ANTENNAS BASED ON THE CAVITY MODEL AND DOMINANT MODE OPERATION FOR EACH. THAT IS: A. TM010 MODE FOR THE RECTANGULAR PATCH B. TM110 MODE FOR THE CIRCULAR PATCH ponnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnn **INPUT PARAMETERS 1. FREQ = RESONANT FREQUENCY F, (in GHz) 2. EPSR = DIELECTRIC CONSTANT OF THE SUBSTRATE & 3. HEIGHT = HEIGHT OF THE SUBSTRATE h (in cm) 4. YO = POSITION OF RECESSED FEED POINT Y. (in cm) RELATIVE TO LEADING RADIATING EDGE OF RECTANGULAR PATCH. NOT NECESSARY FOR CIRCULAR PATCH **OUTPUT PARAMETERS A. RECTANGULAR PATCH: 1. PHYSICAL WIDTH OF PATCH W (in cm) 2. EFFECTIVE LENGTH OF PATCH Le (in cm) 3. PHYSICAL LENGTH OF PATCH L (in cm) 4. NORMALIZED E-PLANE AMPLITUDE PATTERN (in dB) 5. NORMALIZED H-PLANE AMPLITUDE PATTERN (in dB) 6. E-PLANE HALF-POWER BEAMWIDTH (in degrees) 7. H-PLANE HALF-POWER BEAMWIDTH (in degrees) 8. DIRECTIVITY (dimensionless and in dB) 9. RESONANT INPUT RESISTANCE (in ohms) a. AT LEADING RADIATING EDGE (y = 0) D. AT RECESSED FEED POINT FROM LEADING RADIATING EDGE (y = yo) B. CIRCULAR PATCH: 1. PHYSICAL RADIUS OF THE PATCH a (in cm) 2. EFFECTIVE RADIUS OF THE PATCH e (in cm) 3. NORMALIZED E-PLANE AMPLITUDE PATTERN (in dB) 4. NORMALIZED H-PLANE AMPLITUDE PATTERN (in dB) 5. E-PLANE HALF-POWER BEAMWIDTH (in degrees) 6. H-PLANE HALF-POWER BEAMWIDTH (in degrees) 7. DIRECTIVITY (dimensionless and in dB) COMPUTER PROGRAM - MICROSTRIP ANTENNAS THIS IS A FORTRAN PROGRAM THAT DESIGNS AND COMPUTES THE ANTENNA RADIATION CHARACTERISTICS OF: I. RECTANGULAR II. CIRCULAR MICROSTRIP PATCH ANTENNAS BASED ON THE CAVITY MODEL AND DOMINANT MODE OPERATION FOR EACH. THAT IS: A. TM10 MODE FOR THE RECTANGULAR PATCH B. TM110 MODE FOR THE CIRCULAR PATCH nnnnnnnnnnnnnnn0000000000000000000000 **INPUT PARAMETERS 1. FREQ = RESONANT FREQUENCY , (in GHz) 2. EPSR = DIELECTRIC CONSTANT OF THE SUBSTRATE & 3. HEIGHT = HEIGHT OF THE SUBSTRATE h (in cm) 4. YO = POSITION OF RECESSED FEED POINT Y. (in cm) RELATIVE TO LEADING RADIATING EDGE OF RECTANGULAR PATCH. NOT NECESSARY FOR CIRCULAR PATCH **OUTPUT PARAMETERS A. RECTANGULAR PATCH: 1. PHYSICAL WIDTH OF PATCH W (in cm) 2. EFFECTIVE LENGTH OF PATCH Le (in cm) 3. PHYSICAL LENGTH OF PATCH L (in cm) 4. NORMALIZED E-PLANE AMPLITUDE PATTERN (in dB) 5. NORMALIZED H-PLANE AMPLITUDE PATTERN (in dB) 6. E-PLANE HALF-POWER BEAMWIDTH (in degrees) 7. H-PLANE HALF-POWER BEAMWIDTH (in degrees) 8. DIRECTIVITY (dimensionless and in dB) 9. RESONANT INPUT RESISTANCE (in ohms) a. AT LEADING RADIATING EDGE (y=0) b. AT RECESSED FEED POINT FROM LEADING RADIATING EDGE (y = yo) B. CIRCULAR PATCH: 1. PHYSICAL RADIUS OF THE PATCH a (in cm) 2. EFFECTIVE RADIUS OF THE PATCH (in cm) 3. NORMALIZED E-PLANE AMPLITUDE PATTERN (in dB) 4. NORMALIZED H-PLANE AMPLITUDE PATTERN (in dB) 5. E-PLANE HALF-POWER BEAMWIDTH (in degrees) 6. H-PLANE HALF-POWER BEAMWIDTH (in degrees) 7. DIRECTIVITY (dimensionless and in dB) Write a Fortran code for rectangular microstrip antenna that works at 9.40 GHz to find ;radiation diagrams, HPBW, F/B ratio, gain parameters. COMPUTER PROGRAM - MICROSTRIP ANTENNAS THIS IS A FORTRAN PROGRAM THAT DESIGNS AND COMPUTES THE ANTENNA RADIATION CHARACTERISTICS OF: I. RECTANGULAR II. CIRCULAR MICROSTRIP PATCH ANTENNAS BASED ON THE CAVITY MODEL AND DOMINANT MODE OPERATION FOR EACH. THAT IS: A. TM010 MODE FOR THE RECTANGULAR PATCH B. TM110 MODE FOR THE CIRCULAR PATCH ponnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnnn **INPUT PARAMETERS 1. FREQ = RESONANT FREQUENCY F, (in GHz) 2. EPSR = DIELECTRIC CONSTANT OF THE SUBSTRATE & 3. HEIGHT = HEIGHT OF THE SUBSTRATE h (in cm) 4. YO = POSITION OF RECESSED FEED POINT Y. (in cm) RELATIVE TO LEADING RADIATING EDGE OF RECTANGULAR PATCH. NOT NECESSARY FOR CIRCULAR PATCH **OUTPUT PARAMETERS A. RECTANGULAR PATCH: 1. PHYSICAL WIDTH OF PATCH W (in cm) 2. EFFECTIVE LENGTH OF PATCH Le (in cm) 3. PHYSICAL LENGTH OF PATCH L (in cm) 4. NORMALIZED E-PLANE AMPLITUDE PATTERN (in dB) 5. NORMALIZED H-PLANE AMPLITUDE PATTERN (in dB) 6. E-PLANE HALF-POWER BEAMWIDTH (in degrees) 7. H-PLANE HALF-POWER BEAMWIDTH (in degrees) 8. DIRECTIVITY (dimensionless and in dB) 9. RESONANT INPUT RESISTANCE (in ohms) a. AT LEADING RADIATING EDGE (y = 0) D. AT RECESSED FEED POINT FROM LEADING RADIATING EDGE (y = yo) B. CIRCULAR PATCH: 1. PHYSICAL RADIUS OF THE PATCH a (in cm) 2. EFFECTIVE RADIUS OF THE PATCH e (in cm) 3. NORMALIZED E-PLANE AMPLITUDE PATTERN (in dB) 4. NORMALIZED H-PLANE AMPLITUDE PATTERN (in dB) 5. E-PLANE HALF-POWER BEAMWIDTH (in degrees) 6. H-PLANE HALF-POWER BEAMWIDTH (in degrees) 7. DIRECTIVITY (dimensionless and in dB)Step by Step Solution
There are 3 Steps involved in it
Step: 1
Get Instant Access to Expert-Tailored Solutions
See step-by-step solutions with expert insights and AI powered tools for academic success
Step: 2
Step: 3
Ace Your Homework with AI
Get the answers you need in no time with our AI-driven, step-by-step assistance
Get Started