(*For those who have not previously attended this course.*)

*Lecturer: Professor I.M. Leslie*
(`iml@cl.cam.ac.uk`)

*No. of lectures *+* practicals:* 11 + 7

*This course is a prerequisite for VLSI Design *(*Part II*)*.*

**Aims**

The aims of this course are to present the principles of combinational and sequential digital logic, to provide techniques for designing digital logic and to introduce basic physical electronics and MOS gate realisation.

**Lectures**

**Introduction, and combinational logic.**The parts of a simple computer. Logic*versus*technology. Number representation. Boolean algebra. Idealised logic gates. Boolean algebra describes ideal combinational circuits. Normal forms. Simplification of combinational functions. Complexity in combination logic: adders. Dynamic behaviour of combination logic: hazards. Logic levels in real implementations.**Sequential logic design.**State. Finite state automata. State diagrams. Asynchronous and synchronous machines. Sequential logic, flip-flops and delays. Basis for a sequential machine. Fundamental and pulse mode. State assignment and state control. Race conditions. Designing with edge triggered devices. Synchronisation. State minimisation. Initial conditions. Examples.**Technology.**Requirements for logic implementation. Simple electricity. Semiconductors, holes and electrons, junctions, depletion layers. Devices and their properties. Diodes and MOS transistors. nMOS and CMOS circuits. Capacitance and rise and fall times. Output stages and bus arrangements. Fabrication of integrated circuits. Memory implementation and programmable logic.

**Objectives**

At the end of the course students should

- understand the relationships between combination logic
and boolean algebra, and between sequential logic and finite state
machines
- be able to design and minimise combinational logic
- appreciate tradeoffs in complexity and speed of combinational
designs
- understand how state can be stored in a digital logic
circuit
- understand the difference between asynchronous and edge triggered logic
- know how to design a simple finite state machine from a specification
and be able to implement this in gates and edge triggered flip flops
- have a basic understanding of how CMOS technology works and
what factors limit its speed of operation

**Recommended books**

Lewin, M.H. (1983). *Logic Design and Computer Organization*.
Addison-Wesley (out of print).

Dowsing, R.D. & Woodhams, F.W.D. (1990). *Computers from Logic to
Architecture*. Chapman and Hall.

Hayes, J.P. (1993). *Introduction to Digital Logic Design*.
Addison-Wesley.

Mead, C. & Conway, L. (1980). *Introduction to VLSI Systems*.
Addison-Wesley.

Katz, R.H. (1994). *Contemporary Logic Design*. Benjamin/Cummings.