Undergraduate Course: Sigma Delta Data Converters 5 (ELEE11080)
Course Outline
| School | School of Engineering |
College | College of Science and Engineering |
| Course type | Standard |
Availability | Available to all students |
| Credit level (Normal year taken) | SCQF Level 11 (Year 5 Undergraduate) |
Credits | 10 |
| Home subject area | Electronics |
Other subject area | None |
| Course website |
None |
Taught in Gaelic? | No |
| Course description | This course will equip the student with an understanding of
sigma-delta data converters at a theoretical and practical level.
The coursework makes a link between the digital signal processing concepts of sigma delta conversion and implementation in integrated circuit hardware.
The course will briefly review the basics of discrete-time signals and systems, before looking at block diagrams and circuit implementations of modulator structures. Saturation, stability and limit cycle behaviour of modulator loops will be described and related to circuit structure. Non-ideal behaviour of modulators such as noise, matching, finite gain and settling will be related to circuit level implementations.
The course will be illustrated throughout with MATLAB, Simulink and Cadence Verilog A examples linking to laboratory sessions and a design exercise issued at the start of semester. |
Entry Requirements (not applicable to Visiting Students)
| Pre-requisites |
|
Co-requisites | |
| Prohibited Combinations | |
Other requirements | None |
| Additional Costs | None |
Information for Visiting Students
| Pre-requisites | None |
| Displayed in Visiting Students Prospectus? | No |
Course Delivery Information
|
| Delivery period: 2013/14 Semester 2, Available to all students (SV1)
|
Learn enabled: Yes |
Quota: None |
Web Timetable |
Web Timetable |
| Course Start Date |
13/01/2014 |
| Breakdown of Learning and Teaching activities (Further Info) |
Total Hours:
100
(
Lecture Hours 20,
Seminar/Tutorial Hours 10,
Supervised Practical/Workshop/Studio Hours 18,
Summative Assessment Hours 2,
Programme Level Learning and Teaching Hours 2,
Directed Learning and Independent Learning Hours
48 )
|
| Additional Notes |
|
| Breakdown of Assessment Methods (Further Info) |
Written Exam
70 %,
Coursework
30 %,
Practical Exam
0 %
|
| Exam Information |
| Exam Diet |
Paper Name |
Hours:Minutes |
|
|
| Main Exam Diet S2 (April/May) | | 2:00 | | |
Summary of Intended Learning Outcomes
On completion of the course students will be able to:
- understand the operating principles of sigma delta converters
- choose the order, structure and coefficients of sigma delta
modulators at a block level
- employ SIMULINK and MATLAB to simulate and design the modulator
coefficients
- use Cadence to study non-ideal effects in modulators
- propose circuit implementations of modulators
- understand the range of applications of sigma-delta converters. |
Assessment Information
70% Exam
30% Assignment |
Special Arrangements
| None |
Additional Information
| Academic description |
Not entered |
| Syllabus |
Lecture 1:
Reminder of the basics of discrete-time signals and systems.
Topics include: sampling, aliasing,interpolation, reconstruction, quantization modelled as noise, and the effects of sampling jitter. General block diagram of oversampled system (ADC and DAC, decimation and interpolation). Frequency domain representation of signals and noise. Fourier series, Fourier transforms and computer-based computational techniques, including the Discrete Fourier Transform (DFT), Fast Fourier Transform (FFT), windowing and coherent
sampling principles. Power spectral density (PSD). Averaging
to reduce quantisation noise. Sincx.
Lecture 2:
The principles of delta-sigma modulation.
Principle of oversampling to reduce the effects of quantization noise, followed by noise-shaping to enhance performance. Block diagram of 1st order modulator. Time-domain model using a first-order lowpass system then followed by a frequency-domain description. Z-transfer function of NTF and
STF. In-band and filtered noise. Power of noise and signal,
SNR formula. Quantiser gain. Limit cycles, idle tones and
dither. Simulink examples.
Lecture 3:
Second order modulators.
Second-order modulator block diagrams. Z-transfer function of NTF, STF. MASH implementation. Single loop implementation. Comparison of 1st and 2nd order. Saturation. Dynamic range scaling equalisation at internal nodes. Limit cycles. Formula of
SNR with modulator order and oversampling. Simulink examples.
Lecture 4:
Higher order modulators.
Higher-order block diagram. Implmentation of higher order modulator as MASH or single loop. Instability. General higher order modulator. Placement of zeros in NTF. Feedback/feedforward to improve THD. NTF comparison. Bandpass. Improvement of stability by multibit quantisation and feedback. Matlab SD toolbox for design.
Lecture 5:
Sigma-delta DAC.
Sigma-delta modulation in digital domain. DAC matching. Multi-bit DAC. Mismatch effects on linearity. Randomised selection of elements. Dynamic element matching (DEM). Data weighted averaging (DWA). Tones. Tree DEM. Multi-bit feedback in ADC. Switched capacitor output filter. kT/C noise.
Lecture 6:
Circuit Implementation of Modulators.
Switched capacitor implementation of 1st order and 2nd order. DAC requirements. Half delay and feedthrough integrators, settling. Choice of capacitor ratios. Dynamic range scaling equalisation at internal nodes Differential/single ended. Cadence Verilog A examples.
Lecture 7:
Transistor Level Implementation of Modulators.
OTA and Opamp implementations. Comparator implementations. Gm-C modulators. Power consumption optimisation.
Lecture 8:
Non-ideal effects in Sigma-delta modulators.
Matching, finite opamp gain, incomplete settling, 1/f and thermal noise. Effect on MASH, single loop etc. Cadence Verilog A examples.
Lecture 9: Digital filter implementation Filter order choice related to loop order. Comb filters. Reduction in sample frequency. Hardware requirements. Filter transfer function design. FIR, IIR filter implementation. Raised Cosine. Elliptic/Chebyshev. Decimation and interpolation filters. Power consumption/gate area.
Lecture 10:
Modulator Applications.
Frequency synthesizers, audio recording, Class-D audio, high
frequency modulators. Multi-standard comms. Gm-C implementations. State of the art (p358-359 Schreier)
Lecture 11:
Guest lecture. |
| Transferable skills |
Not entered |
| Reading list |
Understanding Sigma-Delta Data Converters, Schreier and
Temes, IEEE Press, ISBN 978-0-471-46585-0 |
| Study Abroad |
Not entered |
| Study Pattern |
One lecture per week.
A laboratory session every two weeks. |
| Keywords | Sigma-delta, delta-sigma, analogue to digital, digital to analogue, integrated circuits |
Contacts
| Course organiser | Dr Robert Henderson
Tel: (0131 6)50 5645
Email: Robert.Henderson@ed.ac.uk |
Course secretary | Mrs Sharon Potter
Tel: (0131 6)51 7079
Email: Sharon.Potter@ed.ac.uk |
|
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