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ویرایش:
نویسندگان: A.I.Zverev А. И. Зверев
سری:
ناشر: John Wiley and Sons, Inc.
سال نشر: 1967
تعداد صفحات: 592
زبان: English
فرمت فایل : DJVU (درصورت درخواست کاربر به PDF، EPUB یا AZW3 تبدیل می شود)
حجم فایل: 17 مگابایت
در صورت تبدیل فایل کتاب Handbook of Filter Synthesis به فرمت های PDF، EPUB، AZW3، MOBI و یا DJVU می توانید به پشتیبان اطلاع دهید تا فایل مورد نظر را تبدیل نمایند.
توجه داشته باشید کتاب راهنمای سنتز فیلتر نسخه زبان اصلی می باشد و کتاب ترجمه شده به فارسی نمی باشد. وبسایت اینترنشنال لایبرری ارائه دهنده کتاب های زبان اصلی می باشد و هیچ گونه کتاب ترجمه شده یا نوشته شده به فارسی را ارائه نمی دهد.
This treatment of the electric wave filter is for electronic systems engineers engaged in communication, radar, and any other electronic equipment that depends on selective networks. From the systems engineers point of view the filter sets the standards of the system. Today he is able to specify almost any type of stable, single-valued analytic function as a subsystem on a block diagram, with reasonable assurance that it can be approximated and built into an operating unit. The exact mathematical technique is so successful that the newer electronic systems are literally packed with synthesized passive and active networks. An exact knowledge of filter performance is therefore essential for the systems engineer. In this book he can find information concerning the performance of all possible types of filters in both the time and frequency domains. In addition, the filter expert can find here a variety of general and specific information pertinent to his speciality. Almost any type of filter can be designed with the aid of the precalculated data presented...ContentsCHAPTER 1 FILTERS IN ELECTRONICS1.1 Types of Filters1.2 Filter Applications1.3 All-Pass Filters1.4 Properties of Lattice Filters1.5 Filter Building Blocks1.6 Higher Order Filters1.7 Coil-Saving Bandpass Filters1.8 Frequency Range of Applications1.9 Physical Elements of the Filter1.10 Active Bandpass Filters1.11 RC Passive and Active Filters1.12 Microwave Filters1.13 Parametric FiltersCHAPTER 2 THEORY OF EFFECTIVE PARAMETERS2.1 Power Balance2.2 Types of General Network Equations2.3 Effective Attenuation2.4 Reflective (Echo) Attenuation2.5 Transmission Function As a Function Of Frequency Parameter, s2.6 Polynomials of Transmission and Filtering Functions2.7 Filter Networks2.8 Voltage and Current Sources2.9 The Function D(s) As An Approximation Function2.10 Examples of Transmission Function Approximation2.11 Simplest Polynomial Filters in Algebraic Form2.12 Introduction To Image-Parameter Theory2.13 Bridge Networks2.14 Examples of Realization in the Bridge Form2.15 Hurwitz Polynomial2.16 The Smallest Realizable Networks2.17 Fourth-Order Networks2.18 Fifth-Order NetworksCHAPTER 3 FILTER CHARACTERISTICS IN THE FREQUENCY DOMAIN3.1 Amplitude Responses3.2 Phase-and Group-Delay Responses3.3 Group Delay of an Idealized Filter3.4 Group-Delay—Attenuation Relationship3.5 The Chebyshev Family of Response Characteristics3.6 Gaussian Family of Response Characteristics3.7 A Filter with Transitional Magnitude Characteristics3.8 Legendre Filters3.9 Minimum-Loss Characteristics3.10 Synchronously Tuned Filters3.11 Arithmetically Symmetrical Bandpass Filters3.12 Attenuation Characteristics of Image Parameter Filters3.13 Other Types of Filter Characteristics3.14 Plots of the Attenuation and Group Delay CharacteristicsCHAPTER 4 ELLIPTIC FUNCTIONS AND ELEMENTS OF REALIZATION4.1 Double Periodic Elliptic Functions4.2 Mapping of s-Plane into w-Plane4.3 First Basic Transformation of Elliptic Functions4.4 Filtering Function in z-Plane4.5 Graphical Representation of Parameters4.6 Characteristic Values of D(s)4.7 An Example of Filter Design4.8 Consideration of Losses4.9 Introduction of Losses by Frequency Transformation4.10 Highpass Filters with Losses4.11 Transmission Functions with Losses4.12 Conclusions on Consideration of Losses4.13 Realization Process4.14 Bandpass Filter with a Minimum Number of Inductors4.15 The Elements of a Coil-Saving Network4.16 Consideration of Losses in Zig-Zag Filters4.17 Realization Procedure4.18 Numerical Example of Realization4.19 Full and Partial Removal for a Fifth-Order FilterCHAPTER 5 THE CATALOG OF NORMALIZED LOWPASS FILTERS5.1 Introduction to the Catalog5.2 Real Part of the Driving Point Impedance5.3 Lowpass Filter Design5.4 Design of Highpass Filters5.5 Design of LC Bandpass Filters5.6 Design of Narrowband Crystal Filters5.7 Design of Bandstop Filters5.8 Catalog of Normalized Lowpass ModelsCHAPTER 6 DESIGN TECHNIQUES FOR POLYNOMIAL FILTERS6.1 Introduction to Tables of Normalized Element Values6.2 Lowpass Design Examples6.3 Bandpass Filter Design6.4 Concept of Coupling6.5 Coupled Resonators6.6 Second-Order Bandpass Filter6.7 Design with Tables of Predistorted k and q Parameters6.8 Design Examples using Tables of k and q Values6.9 Tables of Lowpass Element Values6.10 Tables of 3-dB Down k and q ValuesCHAPTER 7 FILTER CHARACTERISTICS IN THE TIME DOMAIN7.1 Introduction to Transient Characteristics7.2 Time and Frequency Domains7.3 Information Contained in the Impulse Response7.4 Step Response7.5 Impulse Response of an Ideal Gaussian Filter7.6 Residue Determination7.7 Numerical Example7.8 Practical Steps in the Inverse Transformation7.9 Inverse Transform of Rational Spectral Functions7.10 Numerical Example7.11 Estimation Theory7.12 Transient Response in Highpass and Bandpass Filters7.13 The Exact Calculation of Transient Phenomena for Highpass Systems7.14 Estimate of Transient Responses in Narrowband Filters7.15 The Exact Transient Calculation in Narrowband Systems7.16 Group Delay Versus Transient Response7.17 Computer Determination of Filter Impulse Response7.18 Transient Response CurvesCHAPTER 8 CRYSTAL FILTERS8.1 Introduction8.2 Crystal Structure8.3 Theory of Piezoelectricity8.4 Properties of Piezoelectric Quartz Crystals8.5 Classification of Crystal Filters8.6 Bridge Filters8.7 Limitation of Bridge Crystal Filters8.8 Spurious Response8.9 Circuit Analysis of a Simple Filter8.10 Element Values in Image-Parameter Formulation8.11 Ladder Filters8.12 Effective Attenuation of Simple Filters8.13 Effective Attenuation of Ladder Networks8.14 Ladder Versus Bridge Filters8.15 Practical Differential Transformer for Crystal Filters8.16 Design of Narrowband Filters with the Aid of Lowpass Model8.17 Synthesis of Ladder Single Sideband Filters8.18 The Synthesis of Intermediate Bandpass Filters8.19 Example of Band-Reject Filter8.20 Ladder Filters with Large BandwidthCHAPTER 9 HELICAL FILTERS9.1 Introduction9.2 Helical Resonators9.3 Filter with Helical Resonators9.4 Alignment of Helical Filters9.5 Examples of Helical FilteringCHAPTER 10 NETWORK TRANSFORMATIONS10.1 Two-Terminal Network Transformations10.2 Delta-Star Transformation10.3 Use of Transformer in Filter Realization10.4 Nortons Transformation10.5 Applications of Mutual Inductive Coupling10.6 The Realization of LC Filters with Crystal Resonators10.7 Negative and Positive Capacitor Transformation10.8 Bartletts Bisection Theorem10.9 Cauers Equivalence10.10 Canonic Bandpass Structures10.11 Bandpass Ladder Filters Having a Canonical Number of Inductors without Mutual Coupling10.12 Impedance and Admittance Inverters10.13 Source and Load TransformationBIBLIOGRAPHY