| Capaian Pembelajaran Mata Kuliah (CPMK) | - Kemampuan untuk menerapkan hubungan ilmiah dan matematis (prinsip atau hukum) dan masukan yang diperlukan untuk masalah mengenai Prinsip Sistem Komunikasi Dijital, Sinyal dan sistem, Konsep Pemgkodean Kanal
- Kemampuan mengidentifikasi dan merumuskan permasalahan teknik mengenai Prinsip Sistem Komunikasi Dijital, Sinyal dan sistem, Konsep Pemgkodean Kanal
- Kemampuan menganalisis dan menyelesaikan permasalahan teknik mengenai Prinsip Sistem Komunikasi Dijital, Sinyal dan sistem, Konsep Pemgkodean Kanal
- Kemampuan menerapkan penggunaan piranti teknik modern dan mengintegrasikan dalam proyek rekayasa mengenai Prinsip Sistem Komunikasi Dijital, Sinyal dan sistem, Konsep Pemgkodean Kanal
| - Ability to apply scientific and mathematical relationships (principles or laws) and input required for problems regarding Digital Communication Systems Principles, Signals and systems, Channel Coding Concepts
- Ability to identify and formulate technical problems regarding Digital Communication System Principles, Signals and systems, Channel Coding Concepts
- Ability to analyze and solve technical problems regarding Digital Communication System Principles, Signals and systems, Channel Coding Concepts
- Ability to apply the use of modern engineering tools and integrate in engineering projects regarding the Principles of Digital Communication Systems, Signals and systems, Channel Coding Concepts
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| Catatan Tambahan | Silabus kuliah :
1. Konsep proses acak dan pemodelan derau: deskripsi proses acak, karakteristik
statistik, definisi sifat stasioner, transmisi proses acak melalui sistem linier, AWGN
2. Perhitungan kinerja pada transmisi baseband: konsep perhitungan kinerja, peluang
kesalahan pada penerima integrate-and-dump, deteksi dengan matched filter dan
korelator, intersymbol interference (ISI), pola mata, syarat Nyquist untuk transmisi
bebas ISI, raised cosine, ekualisasi baseband, transmisi sinyal dengan M-ary PAM
3. Analisis ruang sinyal: konsep ruang sinyal dan kaitannya dengan perhitungan
kinerja
4. Transmisi sinyal dengan modulasi: modulasi digital amplituda (ASK) dan fasa
(PSK) biner, metoda deteksi koheren dan non-koheren, modulasi digital fasa (PSK)
multilevel, modulasi digital hybrid APSK (amplitude/phase shift keying), modulasi
digital frekuensi (FSK), MSK, pengkodean diferensial dan modulasi (biner dan
multilevel)
5. Sinkronisasi: sinkronisasi gelombang pembawa, sinkronisasi simbol, dan
sinkronisasi frame
6. Pengkodean kanal: Hamming distance, kode blok dan kode konvolusi
7. Pengantar sistem spektral tersebar: DSSS, FHSS
8. Pengantar sistem orthogonal frequency division multiplexing: modulasi multi
carrier (MCM), hubungan OFDM , MCM, dan FFT | Cuurse Syllabus :
1. Random process concept and noise modeling: random process description, characteristics
statistics, stationary property definition, random process transmission through linear systems, AWGN
2. Performance calculation on baseband transmission: performance calculation concept, opportunity
Errors in the integrate-and-dump receiver, detection with matched filters and
correlator, intersymbol interference (ISI), eye pattern, Nyquist requirements for transmission
ISI-free, raised cosine, baseband equalization, signal transmission with M-ary PAM
3. Signal space analysis: the concept of signal space and its relation to calculation
Performance
4. Signal transmission with modulation: amplitude digital modulation (ASK) and phase
(PSK) binary, coherent and non-coherent detection methods, phase digital modulation (PSK)
multilevel, APSK hybrid digital modulation (amplitude/phase shift keying), modulation
digital frequency (FSK), MSK, differential coding and modulation (binary and
multilevel)
5. Synchronization: synchronization of carrier waves, synchronization of symbols, and
frame synchronization
6. Channel encoding: Hamming distance, block code and convolution code
7. Introduction to scattered spectral systems: DSSS, FHSS
8. Introduction of orthogonal frequency division multiplexing system: multi modulation
carrier (MCM), OFDM, MCM, and FFT relationships |
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