Day 1

Introduction to Filter Design, Optimization, and Port Tuning

We will present the briefest possible introduction to basic filter design concepts. Starting with lowpass prototypes, we will touch on Chebyshev and elliptic prototypes and finding prototype element values.

Next we will turn to a brief overview of the most common filter design techniques. Topics will include synthesis from an insertion or return loss function, the coupling matrix approach, and synthesis by optimization.

The use of general purpose linear simulators for equal-ripple optimization will also be discussed.

Finally, we will introduce the port tuning concept.

• Basic Filter Concepts
• Chebyshev and Elliptic Prototypes
• Synthesis From Insertion Loss Functions
• Coupling Matrix Approach
• Synthesis by Optimization
• Equal-ripple Optimization
• The Port Tuning Concept

Day 2

Narrow Band Filter Design and EM Simulation

Our approach to narrow band filter design starts with Dishal’s method and moves a step beyond with port tuning of a full EM model. The port tuned model is a virtual prototype that can be diagnosed and optimized before any hardware is built. Modern TEM filters often employ cascade triplets and quads to realize transmission zeros in the stopband or flatten group delay in the passband. These filters can also be designed using our approach. At some point, practical procedures are needed to measure unloaded Q, external Q, and coupling coefficients. Systematic methods for tuning filters are also needed.

All of these methods and procedures can be applied to actual hardware or to an EM simulation of the hardware.

• Narrow Band Filter Design
• Cross-Coupled Filters
• EM Filter Prototypes
• Unloaded Q
• External Q
• Coupling Coefficients
• Filter Tuning

Day 3

Designing Planar Filters

Filters in planar form can be built using several different topologies and technologies. Various single and multilayer ceramic and soft substrate (PCB) technologies are available to the filter designer.

We will cover the more common distributed topologies including edge-coupled, hairpin, and interdigital. More recent coupled and cross-coupled loop topologies will also be presented. At lower microwave frequencies a pseudo-lumped approach using printed inductors and capacitors is more space efficient. Lowpass, elliptic lowpass, and bandpass filters using this approach will be presented.

Strategies for efficient design and EM simulation will be discussed for all the topologies presented.

• Planar Filters
• Edge-coupled, Hairpin, and Interdigital
• Coupled and Cross-coupled Loops
• Pseudo-lumped Lowpass and Bandpass
• Strategies for Design and EM Simulation