Case Studies in Mathematical Modeling for Medical Devices

Name: Case Studies in Mathematical Modeling for Medical Devices
Author: John Crowe

How Pulse Oximeters and Doppler Ultrasound Fetal Heart Rate Monitors Work

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Paperback, blz. | Engels

Elsevier Science | e druk, 2024

ISBN13: 9780323954723

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Elsevier Science e druk, 2024 9780323954723

€ 167,80

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Case Studies in Mathematical Modelling for Medical Devices: How Pulse Oximeters and Doppler Ultrasound Fetal Heart Rate Monitors Work focuses on two medical devices: pulse oximeters and Doppler ultrasound fetal heart rate monitors. The mathematical topics needed to explain their operation from first principles are introduced. These broadly cover the statistics of random processes and Fourier based signal processing. They are used to explain the devices’ operation from first principles to how clinically relevant information is extracted from the devices’ raw outputs. .

The book is for MSc and PhD students working in the area who want a quick, clear introduction to the topics, upper-division undergrads as part of biomedical engineering or applied math degree courses, biomedical engineers looking for a quick "refresher course" and clinicians interested in the operation of the instruments they use.

Specificaties

ISBN13:9780323954723

Taal:Engels

Bindwijze:Paperback

Uitgever:Elsevier Science

Inhoudsopgave

Preface ix Acknowledgments xi Introduction to the book xiii PART 1 Maths for oximetry List of symbols and abbreviations 3 1. Introduction 7 2. Discrete probability distributions 9 3. Continuous probability distributions 17 4. Summary statistics, moments, and cumulants 29 5. Commonly encountered distributions 43 6. Shifting and scaling distributions 61 7. Random samples fromdistributions 67 PART 2 Oximeters 8. Introduction: oximetry 79 9. Absorption coefficients 89 10. Lambert–Beer law 97 11. Oximetry on non-scattering samples 105 12. Scattering and the Lambert–Beer law 113 13. Attenuation versus absorption—a theoretical derivation 123 14. Pulse oximetry 135 15. Pulse oximetry on a population 147 16. TheMasimo Corporation’s oximeters 153 17. Modeling light propagation 163 18. The oximeter zoo 177 PART 3 Appendices for oximeters 19. Variance via raw moments 197 20. Taylor series 199 21. Binomial coefficients and series 201 22. Calculus 205 23. Derivatives of attenuation versus absorbance 215 24. Modeling the PPG 217 25. Fluorescence lifetimemeasurements 219 26. Logarithms 223 PART 4 Maths for DUS-FHR List of symbols and abbreviations 229 27. Introduction 231 28. Waves 237 29. Sinusoids 241 30. Beats 249 31. Fourier analysis 253 32. Frequency domain filtering 263 33. Hilbert transform and the analytic signal 269 34. Convolution 279 35. Modulation 285 36. Sampling 293 37. Autocorrelation 299 PART 5 DUS-FHR 38. Fetal heart rate monitoring 307 39. Ultrasound 313 40. Doppler ultrasound 317 41. Doppler shift extraction 329 42. DUS-FHRmonitoring 355 43. Bandpass sampling 371 44. Pulsed operation 387 PART 6 Appendices for DUS-FHR 45. Compound angle identities 395 46. Complex numbers 397 47. Modeling with Matlab® 399 Bibliography 409 Index 413

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Case Studies in Mathematical Modeling for Medical Devices

How Pulse Oximeters and Doppler Ultrasound Fetal Heart Rate Monitors Work

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