FBE- Elektronik Mühendisliği Lisansüstü Programı

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http://hdl.handle.net/11527/27
Elektronik ve Haberleşme Mühendisliği Ana Bilim Dalı altında bir lisansüstü programı olup, yüksek lisans ve doktora düzeyinde eğitim vermektedir. İTÜ Elektronik ve Haberleşme Mühendisliği Bölümü'nün amacı, mühendis ve mühendis adayı öğrencilere, elektronik ve haberleşme düzen ve sistemlerinin tasarım, geliştirme, üretim ve çalışmaları konusunda sağlam bir bilimsel ve teknik bilgi birikimi kazandırmaktır.

Gözat

Yazar "Akçakaya, Ergül" ile FBE- Elektronik Mühendisliği Lisansüstü Programı'a göz atma
  • Öge
    Akustik kitle dalga esasına dayanan rezonatörlerin analizi ve tasarımı
    (Fen Bilimleri Enstitüsü, 1993) Tufan, Emir ; Akçakaya, Ergül ; 39133 ; Elektronik Mühendisliği
    Bu çalışmada çok katlı kitle dalgası rezonatörleri bilgisayar yardımıyla incelenmiştir. Kitle dalgası rezonatörlerinde rezonans frekansını bir çok parametresi yanında kalınlığı belirler. Rezonans frekansının yüksek olması için kristal malzeme çok ince seçilmelidir. Bunun için piezoelekt rik kristal malzeme belirli yöntemlerle çok ince olarak bir taban üzerine yerleştirilir. Böylelikle akustik dalga taban malzemesinden dönüştürücüye geri yansır ve duran dalga oluşur. Dönüştürücünün çok ince seçilmesiyle rezonans frekansı GHz'ler mertebesine kadar arttırılabilir. Fakat dönüştürücünün yerleştirildiği taban malzemesinin etkisiyle enerji kaybı artar. Bu etkiyi minimize etmek amacıyla çok katlı kitle dalgası rezonatör modeli geliştirilmiştir. Taban malzemesiyle dönüştürücü arasına tabakalar yerleştirilerek iletilen dalganın kendi üzerine birçok kez yansıtılması sağlannmışt ı r. Böylece tek katlı kitle dalgası rezonatöründe dönüştürücünün yerleştirildiği taban malzemesinin etkisi minimize edilmiştir. Dönüştürücü ile taban malzemesi arasına yerleştirilen tabakaların sayısına ve karakteristik empedansları nı n oranına bağlı olarak yansıma katsayısının frekansla değişimi incelenmiştir. Bu değişim gözönünde bulundurularak tam yansımann olduğu tabaka sayısı ve empedans oranlarına sahip yapı oluşturulmuştur. Dönüştürücülerin analizinde kullanmak üzere söz konusu devre modelini esas alan analiz programı gaiıştirılmişti r. Analız yöntemleri filtre analizi için de uygundur.
  • Öge
    Yüzey akustik dalga esasına dayanan filtre ve rezonatörlerin analizi ve tasarımı
    (Fen Bilimleri Enstitüsü, 1992) Cömert, Şenay ; Akçakaya, Ergül ; 22068 ; Elektronik Mühendisliği
    The applicability of surface wave devices to practical electronic systems is basically determined by the centre frequencies, bandwidths and delays obtainable. The upper limit for the centre frequency is determined by fabrication techniques, and current lithography is about 1.5 GHz. At low frequencies SAW devices become more bulky and expensive and other technologies become more suitable, for example bulk acoustic wave resonators for bandpass filters or digital techniques for signal processing. Consequent 1 y-, SAW devices are not normally used below a few MHz. In most applications this frequency range implies that the devices are used in the I. F. section of ' the system and this has the important consequence that low insertion loss is not generally a priority. For example, bandpass filters have typically 15 to 30 dB loss, and this is acceptable for many applications. Bandwidths generally range from a minimum of about lOO kHz to a maximum of about 50% of the centre frequency. CXIIZ)electrode position and the apodisation function required to reproduce a desired waveform. This procedure is applicable to the design of weighted dispersive filters. Surface wave techniques can be used to produce several types of stable oscillator using SAW resonator. The resonator is basically two reflectors forming a surface wave cavity and a transducer which are used to generate a surface wave packet on the surface. The reflectors are periodic arrays of either metal strips or grooves and reflect when their period is equal to half the SAW wavelength and there is corresponding increase in the array transmission loss. With a large number of strips or grooves, the array reflection coefficient can be very close to unity. For YZCY-cut Z-propagatingD lithium niobate which has an impedance discontinuity of 1.2%, 300 metallic strips are required in the array for a reflection coefficient of 98%. The resonator can give very high Q factors, up to 20,000, giving good stability. Furthermore, highly stable c. w. sources with frequencies up to about 2 GHz can be obtained by using SAW resonators. In this thesis, it will be given an analysis and synthesis procedure using transmission line model for the reflectors. The basic resonator structure is illustrated in Figure 3. Grooved array reflector substrate Figure 3. Two-port surface acoustic wave resonator CXIDThe applicability of surface wave devices to practical electronic systems is basically determined by the centre frequencies, bandwidths and delays obtainable. The upper limit for the centre frequency is determined by fabrication techniques, and current lithography is about 1.5 GHz. At low frequencies SAW devices become more bulky and expensive and other technologies become more suitable, for example bulk acoustic wave resonators for bandpass filters or digital techniques for signal processing. Consequent 1 y-, SAW devices are not normally used below a few MHz. In most applications this frequency range implies that the devices are used in the I. F. section of ' the system and this has the important consequence that low insertion loss is not generally a priority. For example, bandpass filters have typically 15 to 30 dB loss, and this is acceptable for many applications. Bandwidths generally range from a minimum of about lOO kHz to a maximum of about 50% of the centre frequency. CXIIZ)electrode position and the apodisation function required to reproduce a desired waveform. This procedure is applicable to the design of weighted dispersive filters. Surface wave techniques can be used to produce several types of stable oscillator using SAW resonator. The resonator is basically two reflectors forming a surface wave cavity and a transducer which are used to generate a surface wave packet on the surface. The reflectors are periodic arrays of either metal strips or grooves and reflect when their period is equal to half the SAW wavelength and there is corresponding increase in the array transmission loss. With a large number of strips or grooves, the array reflection coefficient can be very close to unity. For YZCY-cut Z-propagatingD lithium niobate which has an impedance discontinuity of 1.2%, 300 metallic strips are required in the array for a reflection coefficient of 98%. The resonator can give very high Q factors, up to 20,000, giving good stability. Furthermore, highly stable c. w. sources with frequencies up to about 2 GHz can be obtained by using SAW resonators. In this thesis, it will be given an analysis and synthesis procedure using transmission line model for the reflectors. The basic resonator structure is illustrated in Figure 3. Grooved array reflector substrate Figure 3. Two-port surface acoustic wave resonator CXIDThe applicability of surface wave devices to practical electronic systems is basically determined by the centre frequencies, bandwidths and delays obtainable. The upper limit for the centre frequency is determined by fabrication techniques, and current lithography is about 1.5 GHz. At low frequencies SAW devices become more bulky and expensive and other technologies become more suitable, for example bulk acoustic wave resonators for bandpass filters or digital techniques for signal processing. Consequent 1 y-, SAW devices are not normally used below a few MHz. In most applications this frequency range implies that the devices are used in the I. F. section of ' the system and this has the important consequence that low insertion loss is not generally a priority. For example, bandpass filters have typically 15 to 30 dB loss, and this is acceptable for many applications. Bandwidths generally range from a minimum of about lOO kHz to a maximum of about 50% of the centre frequency. CXIIZ)electrode position and the apodisation function required to reproduce a desired waveform. This procedure is applicable to the design of weighted dispersive filters. Surface wave techniques can be used to produce several types of stable oscillator using SAW resonator. The resonator is basically two reflectors forming a surface wave cavity and a transducer which are used to generate a surface wave packet on the surface. The reflectors are periodic arrays of either metal strips or grooves and reflect when their period is equal to half the SAW wavelength and there is corresponding increase in the array transmission loss. With a large number of strips or grooves, the array reflection coefficient can be very close to unity. For YZCY-cut Z-propagatingD lithium niobate which has an impedance discontinuity of 1.2%, 300 metallic strips are required in the array for a reflection coefficient of 98%. The resonator can give very high Q factors, up to 20,000, giving good stability. Furthermore, highly stable c. w. sources with frequencies up to about 2 GHz can be obtained by using SAW resonators. In this thesis, it will be given an analysis and synthesis procedure using transmission line model for the reflectors. The basic resonator structure is illustrated in Figure 3. Grooved array reflector substrate Figure 3. Two-port surface acoustic wave resonator CXIDThe applicability of surface wave devices to practical electronic systems is basically determined by the centre frequencies, bandwidths and delays obtainable. The upper limit for the centre frequency is determined by fabrication techniques, and current lithography is about 1.5 GHz. At low frequencies SAW devices become more bulky and expensive and other technologies become more suitable, for example bulk acoustic wave resonators for bandpass filters or digital techniques for signal processing. Consequent 1 y-, SAW devices are not normally used below a few MHz. In most applications this frequency range implies that the devices are used in the I. F. section of ' the system and this has the important consequence that low insertion loss is not generally a priority. For example, bandpass filters have typically 15 to 30 dB loss, and this is acceptable for many applications. Bandwidths generally range from a minimum of about lOO kHz to a maximum of about 50% of the centre frequency.