The course aims to guide the student to the advanced design of radio-frequency and microwave integrated circuits for consumer applications, health care, low power RADAR etc. To this end, the most advanced CAD tools will be presented by the instructor and directly used by the students to design and simulate the main blocks of the radiofrequency front end such as LNA, Mixer, Oscillator, filters etc.
The course aims to guide the student to the advanced design of radio-frequency and microwave integrated circuits for consumer applications, health care, low power RADAR etc. To this end, the most advanced CAD tools will be presented by the instructor and directly used by the students to design and simulate the main blocks of the radiofrequency front end such as LNA, Mixer, Oscillator, filters etc.
The course aims to guide the student to the advanced design of radio-frequency and microwave integrated circuits for consumer applications, health care, low power RADAR etc. To this end, the most advanced CAD tools will be presented by the instructor and directly used by the students to design and simulate the main blocks of the radiofrequency front end such as LNA, Mixer, Oscillator, filters etc.
The course aims to guide the student to the advanced design of radio-frequency and microwave integrated circuits for consumer applications, health care, low power RADAR etc. To this end, the most advanced CAD tools will be presented by the instructor and directly used by the students to design and simulate the main blocks of the radiofrequency front end such as LNA, Mixer, Oscillator, filters etc.
In the oral exam the student's ability to explain correctly the main topics presented during the course at the board will be assessed. In the laboratory report the student must demonstrate the ability to utilize a specific CAD tool (ADS) for RFIC design and simulation.
Methods:
Further information:
33% Laboratory Report (CAD design and simulation + report); 67% Oral exam
In the oral exam the student's ability to explain correctly the main topics presented during the course at the board will be assessed. In the laboratory report the student must demonstrate the ability to utilize a specific CAD tool (ADS) for RFIC design and simulation.
Methods:
Further information:
33% Laboratory Report (CAD design and simulation + report); 67% Oral exam
In the oral exam the student's ability to explain correctly the main topics presented during the course at the board will be assessed. In the laboratory report the student must demonstrate the ability to utilize a specific CAD tool (ADS) for RFIC design and simulation.
Methods:
Further information:
33% Laboratory Report (CAD design and simulation + report); 67% Oral exam
In the oral exam the student's ability to explain correctly the main topics presented during the course at the board will be assessed. In the laboratory report the student must demonstrate the ability to utilize a specific CAD tool (ADS) for RFIC design and simulation.
Methods:
Further information:
33% Laboratory Report (CAD design and simulation + report); 67% Oral exam
Delivery: face to face
Learning activities:
Attendance: Advised
Teaching methods:
Delivery: face to face
Attendance: Advised
Learning activities:
Teaching methods:
Radiofrequency link dimensioning and system level considerations, integrated transceivers: available devices and technologies; design of BJT and MOS Low Noise Amplifiers, oscillators, mixer, PLL, power amplifiers; architectures for fully integrated wireless interfaces; CAD tools for RFIC design; examples of wireless integrated applications: radar on a chip, LNA with integrated antenna for millimiter waves.
Radiofrequency link dimensioning and system level considerations, integrated transceivers: available devices and technologies; design of BJT and MOS Low Noise Amplifiers, oscillators, mixer, PLL, power amplifiers; architectures for fully integrated wireless interfaces; CAD tools for RFIC design; examples of wireless integrated applications: radar on a chip, LNA with integrated antenna for millimiter waves.
Radiofrequency link dimensioning and system level considerations, integrated transceivers: available devices and technologies; design of BJT and MOS Low Noise Amplifiers, oscillators, mixer, PLL, power amplifiers; architectures for fully integrated wireless interfaces; CAD tools for RFIC design; examples of wireless integrated applications: radar on a chip, LNA with integrated antenna for millimiter waves.
Radiofrequency link dimensioning and system level considerations, integrated transceivers: available devices and technologies; design of BJT and MOS Low Noise Amplifiers, oscillators, mixer, PLL, power amplifiers; architectures for fully integrated wireless interfaces; CAD tools for RFIC design; examples of wireless integrated applications: radar on a chip, LNA with integrated antenna for millimiter waves.
The following textbook is recommended; further bibliography will be indicated during the course: Thomas H.Lee "The Design of CMOS Radiofrequency Integrated Circuits", Cambridge University Press, Second Edition, 2004
The following textbook is recommended; further bibliography will be indicated during the course: Thomas H.Lee "The Design of CMOS Radiofrequency Integrated Circuits", Cambridge University Press, Second Edition, 2004
The following textbook is recommended; further bibliography will be indicated during the course: Thomas H.Lee "The Design of CMOS Radiofrequency Integrated Circuits", Cambridge University Press, Second Edition, 2004
The following textbook is recommended; further bibliography will be indicated during the course: Thomas H.Lee "The Design of CMOS Radiofrequency Integrated Circuits", Cambridge University Press, Second Edition, 2004