Gives a number of typical tutorial questions for students to try by themselves. Worked solutions are provided for several of these.

Gives a number of numerical examples. Shows how the stability criteria can be used to infer closed-loop stability from open-loop Nyquist diagrams. Focus is on systems without integrators.

Gives a number of numerical examples which include integrators. Shows how the stability criteria can be used to infer closed-loop stability from open-loop Nyquist diagrams. The inclusion of integrators cmplicates the computation of encirclements and how hence the video gives several examples of how to do this correctly.

Introduces the concept of encirclements, and how to count them, followed by the association to Nyquist diagram. Uses examples to show the key difference between LHP and RHP factors when mapped under the D contour which later is central to the Nyquist stability criteria.

Uses MATLAB demonstrations to show how the shape of the Nyquist diagram (for the loop transfer function) and in particular its proximity to the minus one point seems to have a very strong relationship with the corresponding closed-loop performance. Motivates further study of the potential uses of Nyquist diagrams for analysis and design.

Introduces the stability criteria using a simple derivation of how encirclements of the -1 point in the Nyquist diagram for the open-loop system is related to closed-loop stability, for unity negative feedback.

Introduces the D-contour and its relevance to frequency response diagrams. Shows how the Nyquist diagram is extended when considered as a mapping of the D-contour. Introduces key properties of the complete Nyquist diagram such as symmetry, conformal mappings, right hand turns and rotation where frequency is near zero.

Uses the properties associated to the Nyquist diagram as a mapping of the D-contour. Shows through several examples how these properties allow a rapid production of the complete Nyquist diagram, assuming one already has the sketch associated to positive frequencies. Includes some examples with integrators.

Builds on previous video by giving a number of illustrations of how trends in the gain and phase plots can be used to produce a sketch of the Nyquist diagram relatively quickly. Also illustrates how relatively small changes in pole or zero positions can have substantial impacts on the overall shape. Shows how MATLAB can be used to check working. [Note TWO small errors: (I) in voice over on slide 8 - says anti-clockwise when clearly the direction on the diagram is clockwise. (ii) from...

Gives a number of examples for students to attempt by themselves. Also includes worked solutions.

Develops videos 1-3 by showing how sketching rules need to be modified slightly when a system includes a single integrator. Gives a number of worked examples and then compares answers with those obtained on MATLAB.

RHP factors were discussed extensively in the series on Bode diagrams. Consequently this video reinforces those messages through a few numerical illustrations of sketching Nyquist diagrams from first principles for systems with RHP factors. For completeness, the video also demonstrates the impact that input/output delay will have on a Nyqust diagram, although it is noted it would be difficult in general to form a good sketch for a system with a delay.

Introduces the idea that an effective means of sketching of a Nyquist diagram is to transcribe frequency response gain and phase information. A few useful insights are presented to allow viewers to form sketches quickly from key trends in the gain and phase.

While sketching is intended to be used only when this can be done quickly, or to develop insight, there are times when the initial quadrant of a Nyquist diagram is not obvious. Nevertheless, this information can be critical to the efficacy of the plot for later design and hence this video gives some simple techniques for estimating the initial quadrant correctly, with minimal computation.

Gives the definition of a Nyquist diagram and demonstrates plotting by enumerating frequency response data explicitly.