Sie befinden Sich nicht im Netzwerk der Universität Paderborn. Der Zugriff auf elektronische Ressourcen ist gegebenenfalls nur via VPN oder Shibboleth (DFN-AAI) möglich. mehr Informationen...
Modern analog filter analysis and design : a practical approach
Beschreibungen/Notizen
Description based upon print version of record.
Includes bibliographical references and index.
Modern Analog Filter Analysis and Design: A Practical Approach; Contents; Preface; Abbreviations; 1 Introduction; 2 A Review of Network Analysis Techniques; 2.1 Transformed Impedances; 2.2 Nodal Analysis; 2.3 Loop (Mesh) Analysis; 2.4 Network Functions; 2.5 One-Port and Two-Port Networks; 2.5.1 One-Port Networks; 2.5.2 Two-Port Networks; 2.5.2.1 Admittance Matrix Parameters; 2.5.2.2 Impedance Matrix Parameters; 2.5.2.3 Chain Parameters (Transmission Parameters); 2.5.2.4 Interrelationships; 2.5.2.5 Three-Terminal Two-Port Network; 2.5.2.6 Equivalent Networks
2.5.2.7 Some Commonly Used Nonreciprocal Two-Ports2.6 Indefinite Admittance Matrix; 2.6.1 Network Functions of a Multiterminal Network; 2.7 Analysis of Constrained Networks; 2.8 Active Building Blocks for Implementing Analog Filters; 2.8.1 Operational Amplifier; 2.8.2 Operational Transconductance Amplifier; 2.8.3 Current Conveyor; Practice Problems; 3 Network Theorems and Approximation of Filter Functions; 3.1 Impedance Scaling; 3.2 Impedance Transformation; 3.3 Dual and Inverse Networks; 3.3.1 Dual and Inverse One-Port Networks; 3.3.2 Dual Two-Port Networks; 3.4 Reversed Networks
3.5 Transposed Network3.6 Applications to Terminated Networks; 3.7 Frequency Scaling; 3.8 Types of Filters; 3.9 Magnitude Approximation; 3.9.1 Maximally Flat Magnitude (MFM) Approximation; 3.9.1.1 MFM Filter Transfer Function; 3.9.2 Chebyshev (CHEB) Magnitude Approximation; 3.9.2.1 CHEB Filter Transfer Function; 3.9.3 Elliptic (ELLIP) Magnitude Approximation; 3.9.4 Inverse-Chebyshev (ICHEB) Magnitude Approximation; 3.10 Frequency Transformations; 3.10.1 LP to HP Transformation; 3.10.2 LP to BP Transformation; 3.10.3 LP to BR Transformation; 3.11 Phase Approximation
3.11.1 Phase Characteristics of a Transfer Function3.11.2 The Case of Ideal Transmission; 3.11.3 Constant Delay (Linear Phase) Approximation; 3.11.4 Graphical Method to Determine the BT Filter Function; 3.12 Delay Equalizers; Practice Problems; 4 Basics of Passive Filter Design; 4.1 Singly Terminated Networks; 4.2 Some Properties of Reactance Functions; 4.3 Singly Terminated Ladder Filters; 4.4 Doubly Terminated LC Ladder Realization; Practice Problems; 5 Second-Order Active-RC Filters; 5.1 Some Basic Building Blocks using an OA; 5.2 Standard Biquadratic Filters or Biquads
5.3 Realization of Single-Amplifier Biquadratic Filters5.4 Positive Gain SAB Filters (Sallen and Key Structures); 5.4.1 Low-Pass SAB Filter; 5.4.2 RC:CR Transformation; 5.4.3 High-Pass Filter; 5.4.4 Band-Pass Filter; 5.5 Infinite-Gain Multiple Feedback SAB Filters; 5.6 Infinite-Gain Multiple Voltage Amplifier Biquad Filters; 5.6.1 KHN State-Variable Filter; 5.6.2 Tow-Thomas Biquad; 5.6.3 Fleischer-Tow Universal Biquad Structure; 5.7 Sensitivity; 5.7.1 Basic Definition and Related Expressions; 5.7.2 Comparative Results for ?p and Qp Sensitivities
5.7.3 A Low-Sensitivity Multi-OA Biquad with Small Spread in Element Values
Starting from the fundamentals, the present book describes methods of designing analog electronic filters and illustrates these methods by providing numerical and circuit simulation programs. The subject matters comprise many concepts and techniques that are not available in other text books on the market. To name a few - principle of transposition and its application in directly realizing current mode filters from well known voltage mode filters; an insight into the technological aspect of integrated circuit components used to implement an integrated circuit filter; a careful blending of basi