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This book features an extensive index and all Mathcad worksheets.Vinyl is back, tubes/valves are back, on the high-end field SMD-free analog amplification surpasses digitalized chains, and top microphone manufacturers still set on good old op-amps or on fully discrete BJT, FET, and/or tube-driven amplifiers. There is only one problem that is not satisfyingly well solved by the manufacturers: It is the noise production of the active components and the useful reflection in simulation tools, in tables or graphs of the datasheets/data books.
Nowadays, mostly surrounded by many digital helping tools, it makes sense using them-also by analog aficionados. It saves cost and time simulating first before spending money. Presented in this book the software tool LTSpice which is the free software solution from Linear Technology (today Analog Devices) that could also be used by full analog lovers to simulate the noise production of their amplifier design. All we need is the right creation approach to develop simulation models for the active components. Inter alia this is already done for tubes and BJTs in the 2nd editions of my "How to Gain Gain" and "Balanced Phono-Amps" books. For op-amps, the missing approaches are presented in the book on hand.
It cannot be denied that mathematical software like Mathcad is extremely helpful to find the right equations for graphically presented noise curves which we can find in the literature. Nevertheless, it also works well with other types of math software to fulfill the parameter needs of the here presented modeling approaches for the input referred voltage and current noise of-not only-excellent sounding vintage op-amps, applicable in the audio range from 1 Hz to 100 kHz.
Auteur
Burkhard Vogel achieved the degree Diplom-Ingenieur (Telecommunications) from Darmstadt University of Technology, Germany, in 1973. He then decided to follow a general management career path in the high-tech and IT industry in Germany, Switzerland, and Austria. His passion for music and music systems made Mr. Vogel an expert in Phono-Amps and Vinyl Technology. In addition to "Slopes and Levels," he wrote the RIAA-phono-amp designer guides "The Sound of Silence" and "Balanced Phono-Amps," rounded up by the triode reference "How to Gain Gain".
Texte du rabat
This book features an extensive index and all Mathcad worksheets.
Vinyl is back, tubes/valves are back, on the high-end field SMD-free analog amplification surpasses digitalized chains, and top microphone manufacturers still set on good old op-amps or on fully discrete BJT, FET, and/or tube-driven amplifiers. There is only one problem that is not satisfyingly well solved by the manufacturers: It is the noise production of the active components and the useful reflection in simulation tools, in tables or graphs of the datasheets/data books.
Nowadays, mostly surrounded by many digital helping tools, it makes sense using them-also by analog aficionados. It saves cost and time simulating first before spending money. Presented in this book the software tool LTSpice which is the free software solution from Linear Technology (today Analog Devices) that could also be used by full analog lovers to simulate the noise production of their amplifier design. All we need is the right creation approach to develop simulation models for the active components. Inter alia this is already done for tubes and BJTs in the 2nd editions of my "How to Gain Gain" and "Balanced Phono-Amps" books. For op-amps, the missing approaches are presented in the book on hand.
It cannot be denied that mathematical software like Mathcad is extremely helpful to find the right equations for graphically presented noise curves which we can find in the literature. Nevertheless, it also works well with other types of math software to fulfill the parameter needs of the here presented modeling approaches for the input referred voltage and current noise of-not only-excellent sounding vintage op-amps, applicable in the audio range from 1 Hz to 100 kHz.
Contenu
1 Intro
1.1 Reasons for this Book
1.2 Scope of this Book 1.3 Some Rules for a Better Understanding
2 Basics of OPA Noise and Gain
2.1 Noise Sources of an OPA 2.2 General Aspects of OPA Gains
2.3 Test of "Test-OPA-M" with the Adapted Fig. 1.7 Test Arrangement
2.3.1 Spice parameters for the Test-OPA-M and test arrangement
2.3.2 Noise voltage
2.3.3 Noise Current
2.3.4 Slopes
2.4 Résumé
3 Mathcad Worksheets for Chapter 2
3.1 MCD-WS: Test-OPA-M Open Loop Gain
3.2 MCD-WS: Test-OPA-M Noise Production
4 Non-Inverting OPA Gain Stages
4.1 The Noise Production of the Non-Inverting (Series Configured) OPA Gain Stage
4.2 Output Related
4.3 Input Related
4.4 Résumé
5 Mathcad Worksheet for Chapter 4
5.1 MCD-WS: Non-Inverting Gain Stage
6 Inverting OPA Gain Stages
6.1 The Noise Production of the Inverting (Shunt Configured) OPA Gain Stage
6.2 Output Related
6.3 Input Related
6.4 Résumé
6.5 Important Note Concerning an Additional Load Zx(f) at the (+) Input of the OPA in Fig. 6.2
7 Mathcad Worksheets for Chapter 6
7.1 MCD-WS: Inverting Gain Stage
7.2 MCD-WS: Proof
8 Phono-Amp with OPAs
8.1 The Noise Production of the Phono-Amp
8.2 Main Equations to Calculate the Output Voltage noise and SNs
of the Fig. 8.1 RIAA Phono-Amp - Correlated and Un-Correlated
8.2.1 Main equations for Fig. 8.9 (à la MCD-WS 9.3):
8.2.2 Main equations for Fig. 8.11 (à la MCD-WS 9.3):
8.2.3 Main equations for Fig. 8.1 incl input load (à la MCD-WS 9.3):
8.3 Résumé
9 Mathcad Worksheets for Chapter 8 9.1 MCD-WS: Phono-Amp + 0.0 Ohm with Test-OPA-M
9.2 MCD-WS: Phono-Amp + 1.0 k Ohm with Test-OPA-M
9.3 MCD-WS: Phono-Amp + StaCar with Test-OPA-M
Part II Solutions Other Than Slopes of 0.0 dB/dec or -10.0 dB/dec
10 The Correlation Matter
10.1 OPA with all its Independent Equivalent Input Noise Sources
10.2 The Voltage Noise Question
10.2.1 The 100% un-correlated state
10.2.2 The 100% correlated state
10.2.3 The general state
10.3 The Current Noise Question
10.3.1 The 100% un-correlated state
10.3.2 The 100% correlated state
10.3.3 The general state
10.4 Real OPAs
10.4.1 Model vs. Data Sheet - Results
10.4.2 Recommended approach to find the correlation state of OPAs,
demonstrated by application of the example OPA AD797
10.5 Résumé
11 Mathcad Worksheets for Chapter 10
11.1 MCD-WS: Test-OPA-01 Correlation Basics
11.2 MCD-WS: AD797 Correlation Basics
11.3 MCD-WS: LT1128 Correlation Basics
12 OPA Noise Modelling
12.1 Intro
12.2 Noise Traces of OPAs
12.3 Goals
12.4 The Voltage Noise Solution
12.5 The Current Noise Solution I - Non-inverted and Non-Correlated Version
12.6 The Current Noise Solution II - Inverted and Correlated Version
12.7 The Final Replacement OPA with Independent and Adjustable Noise Sources
12.7.1 OPA without any correlation of the noise sources
12.7.2 OPA including inverted and 100% correlated current noise sources
12.7.3 Other correlation arrangements
12.8 Comparison Results
13 Mathcad Worksheets for Chapter 12
13.1 MCD-WS: Traces
13.2 MCD-WS: Phono-Amp + StaCar with Test-OPA-N
13.3 MCD-WS: Phono-Amp + 1.0 k Ohm with Test-OPA-N
13.4 MCD-WS: Phono-Amp + 0.0 Ohm with Test-OPA-N
Part III Solutions for a Selection of Real Op-Amps
14 Noise Traces for the Simulation Model of OPAs
14.1 Intro
14.2 The Simulation Model's Traces Presented by the Manufacturer
14.3 Data Collection
14.4 Decision about the "right" Traces
14.4.1 Voltage Noise
14.4.2 Current Noise
14.5 Further Material of Noise Trace 14.6 The Final NE5534AN Simulation Model for the New NE5534AN
14.7 What About the Correlation of the Current Noise Sources
of the Original Model?
14.8 What about the…