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100   $a20070129d2006      uy         0
101 0 $aeng
135   $aurcn|||||||||
181   $ctxt
182   $cc
183   $acr
200 10$aHall-effect sensors $etheory and applications /$fby Edward Ramsden
205   $a2nd ed.
210   $aAmsterdam ;$aBoston $cElsevier/Newnes$dc2006
215   $a1 online resource (265 p.)
300   $aDescription based upon print version of record.
311 08$a9780750679343 
311 08$a0750679344 
320   $aIncludes bibliographical references and index.
327   $aFront Cover; Hall-Effect Sensors: Theory and Applications; Copyright Page; Contents; Chapter 1. Hall-Effect Physics; 1.1 A Quantitative Examination; 1.2 Hall Effect in Metals; 1.3 The Hall Effect in Semiconductors; 1.4 A Silicon Hall-Effect Transducer; Chapter 2. Practical Transducers; 2.1 Key Transducer Characteristics; 2.2 Bulk Transducers; 2.3 Thin-Film Transducers; 2.4 Integrated Hall Transducers; 2.5 Transducer Geometry; 2.6 The Quad Cell; 2.7 Variations on the Basic Hall-Effect Transducer; 2.8 Examples of Hall Effect Transducers; Chapter 3. Transducer Interfacing
327   $a3.1 An Electrical Transducer Model 3.2 A Model for Computer Simulation; 3.3 Voltage-Mode Biasing; 3.4 Current-Mode Biasing; 3.5 Amplifiers; 3.6 Amplifier Circuits; 3.7 Analog Temperature Compensation; 3.8 Offset Adjustment; 3.9 Dynamic Offset Cancellation Technique; Chapter 4. Integrated Sensors: Linear and Digital Devices; 4.1 Linear Sensors; 4.2 Linear Transfer Curve; 4.3 Drift; 4.4 Ratiometry; 4.5 Output Characteristics; 4.6 Bandwidth; 4.7 Noise; 4.8 Power Supply Requirements for Linear Sensors; 4.9 Temperature Range; 4.10 Field-Programmable Linear Sensors; 4.11 Typical Linear Devices
327   $a4.12 Switches and Latches 4.13 Definition of Switch vs. Latch; 4.14 Switchpoint Stability; 4.15 Bipolar Switches; 4.16 Power Supply Requirements for Digital Sensors; 4.17 Output Drivers; 4.18 Typical Digital Devices; Chapter 5. Interfacing to Integrated Hall-Effect Devices; 5.1 Interface Issues-Linear Output Sensors; 5.2 Offset and Gain Adjustment; 5.3 Output Thresholding; 5.4 Interfacing to Switches and Latches; 5.5 The Pull-Up Resistor; 5.6 Interfacing to Standard Logic Devices; 5.7 Discrete Logic; 5.8 Driving Loads; 5.9 LED Interfaces; 5.10 Incandescent Lamps
327   $a5.11 Relays, Solenoids, and Inductive Loads 5.12 Wiring-Reduction Schemes; 5.13 Encoding and Serialization; 5.14 Digital-to-Analog Encoding; 5.15 Mini-Networks; 5.16 Voltage Regulation and Power Management; Chapter 6. Proximity-Sensing Techniques; 6.1 Head-On Sensing; 6.2 Slide-By Sensing; 6.3 Magnet Null-Point Sensing; 6.4 Float-Level Sensing; 6.5 Linear Position Sensing; 6.6 Rotary Position Sensing; 6.7 Vane Switches; 6.8 Some Thoughts on Designing Proximity Sensors; Chapter 7. Current-Sensing Techniques; 7.1 Resistive Current Sensing; 7.2 Free-Space Current Sensing
327   $a7.3 Free-Space Current Sensors II 7.4 Toroidal Current Sensors; 7.5 Analysis of Slotted Toroid; 7.6 Toroid Material Selection and Issues; 7.7 Increasing Sensitivity with Multiple Turns; 7.8 An Example Current Sensor; 7.9 A Digital Current Sensor; 7.10 Integrated Current Sensors; 7.11 Closed-Loop Current Sensors; Chapter 8. Speed and Timing Sensors; 8.1 Competitive Technologies; 8.2 Magnetic Targets; 8.3 Vane Switches; 8.4 Geartooth Sensing; 8.5 Geartooth Sensor Architecture; 8.6 Single-Point Sensing; 8.7 Single-Point/Fixed-Threshold Schemes; 8.8 Single-Point/Dynamic-Threshold Schemes
327   $a8.9 Differential Geartooth Sensors
330   $aWithout sensors most electronic applications would not exist-sensors perform a vital function, namely providing an interface to the real world. Hall effect sensors, based on a magnetic phenomena, are one of the most commonly used sensing technologies today. In the 1970's it became possible to build Hall effect sensors on integrated circuits with onboard signal processing circuitry, vastly reducing the cost and enabling widespread practical use. One of the first major applications was in computer keyboards, replacing mechanical contacts. Hundreds of millions of these devices are now manufactured
606   $aHall effect
606   $aDetectors
615  0$aHall effect.
615  0$aDetectors.
676   $a681/.2
700   $aRamsden$b Ed$01798582
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910953973403321
996   $aHall-effect sensors$94341428
997   $aUNINA