Implantable的問題，透過圖書和論文來找解法和答案更準確安心。 我們找到下列推薦必買和特價產品懶人包

Human Medical Thermography

為了解決Implantable的問題，作者Campbell, James Stewart,Mead, M. Nathaniel 這樣論述：

Dr James Stewart Campbell received his bachelor’s degree in Electrical Engineering from Lehigh University in 1966, and then went on to study medicine at the Albany Medical College in Albany, NY, receiving his MD degree in 1970. After completing a straight-surgical internship at the University of Was

hington, he helped found The Country Doctor Clinic in Seattle and practiced general medicine there until 1975. In 1976, Dr. Campbell sfounded the nonprofit Mountain Peoples’ Clinic and had a successful practice of general medicine. He also taught electronics at Tri-County Community College in Murphy

, NC.Dr. Campbell took a leave from clinical medicine in 1986 to work in biomedical engineering, specializing in biological-to-electronic interfacing. His design projects have included air plethysmography, non-invasive blood pressure devices, ultrasound imaging and flowmeters, photo-plethysmography,

fluorescence microscopy, bio-impedance, bio-acoustics, intra-cardiac sensor-stimulators, and implantable neural probe systems.In 2010, Dr. Campbell started a thermography service for Integrative Life Solutions Inc. in Clemmons, NC. Over the next 7 years, the practice became a successful provider of

general and breast thermography. After retiring from medical practice in 2017, he assembled the wealth of objective thermal data from the service into a huge spreadsheet derived from over one thousand imaging sessions. These thermal images and numerical data, along with much additional research and

writing help of his co-author, form the foundation of this book. Dr. Campbell lives in Pfafftown, North Carolina. He is a Life Senior Member of the Institute of Electrical and Electronic Engineers (IEEE), and a Senior Member of the American Academy of Thermology (AAT).M. Nathaniel Mead, MSc, earned

his master’s degree in Nutritional Epidemiology from the UNC Gillings School of Global Public Health. Through his work as a medical-scientific writer, he has over 40 scientific articles listed on PubMed, including papers published in the International Journal of Cancer, Journal of the National Canc

er Institute, Integrative Cancer Therapies, Environmental Health Perspectives, and Cancer Treatment Reviews. In addition to nine years as a contributing editor to Natural Health magazine, Mead served for 20 years as an editorial board member for Integrative Cancer Therapies (Sage Publications) and a

s a research associate for the Block Center for Integrative Cancer Treatment in Skokie, Illinois. He underwent clinical training in thermography under his coauthor and has lectured at the annual scientific session of the American Academy of Thermology.

Implantable進入發燒排行的影片

應用於移動式 UHF 射頻充電的高效率且寬輸入範圍之電源管理晶片採用自適應負載/輸入功率匹配技術

為了解決Implantable的問題，作者郭浩毅 這樣論述：

近年來由於物聯網的興起，使得環境中佈建的無線感測器之需求快速上升。傳統的無線感測器之能量來源主要藉由化學電池提供，因此要具有較長的生命週期與較小的體積是相當困難的。無線能量擷取技術為透過環境中的能量來驅動電子電路的相關技術，提供無線感測節點所需的能量並且延長電池壽命。RF功率擷取方法是目前最常使用於短距離(數十公尺內)能量傳遞的方法之一，但由於目前的RF能量管理電路的高效率受限於窄小的輸入功率範圍，因此相關的應用依舊十分受限。本論文以應用於物聯網之無線能量擷取系統為出發點，除了使用可重構式技術來改善傳統交直流轉換架構之窄小輸入範圍的能量轉換曲線達成具有大動態輸入範圍之交直流轉換電路外，更藉由

後端包含負載調變電路的MPPT技術與低壓降穩壓器穩定輸出電壓值來提高高輸入功率時整體系統之效率。整體系統以CMOS 0.18μm製程製作，為一個全整合式之積體電路，其寬輸入動態範圍之交直流轉換電路具有54.2%之最佳轉換效率、-19.6dBm之靈敏度與20dB大輸入範圍且高轉換效率(Efficiency > 20%)。高轉換效率的能量擷取與高整合晶片將可以有效地解決過去RF能量擷取的效率不佳及能量浪費等問題，並且可以應用於更多功率以及體積限制的植入式生物感測器系統、智慧感測系統、自動電子收費系統貼片及無線充電等需要無線能量傳輸及穩定輸出電壓值的電路中。

Personalized Health Systems for Cardiovascular Disease

為了解決Implantable的問題，作者Bianchi, Anna M.,Henriques, Jorge,Salcedo, Vicente Traves 這樣論述：

Personalized Health Systems for Cardiovascular Disease is intended for researchers, developers, and designers in the field of p-health, with a specific focus on management of cardiovascular diseases. Biomedical engineers will benefit from coverage of sensors, data transmission, signal processing,

data analysis, home and mobile applications, standards, and all other subject matters developed in this book in order to provide an integrated view of the different and multidisciplinary problems related to p-health systems. However, many chapters will also be interesting to physicians and other pr

ofessionals who operate in the health domain. Students, MS and PhD level, mainly in technical universities, but also in medical schools, will find in this book a complete view of the manifold aspects of p-health, including technical problems related to sensors and software, to automatic evaluation a

nd correct interpretation of the data, and also some legal and regulatory aspects. This book mainly focuses on the development of technology used by people and patients in the management of their own health.New wearable and implantable devices allow a continuous monitoring of chronic patients, with

a direct involvement of clinical centers and physicians. Also, healthy people are more and more interested in keeping their own wellness under control, by adopting healthy lifestyles and identifying any early sign of risk. This is leading to personalized solutions via systems which are tailored to a

specific patient/person and her/ his needs. However, many problems are still open when it comes to p-health systems. Which sensors and parameters should be used? Which software and analysis? When and how? How do you design an effective management plan for chronic pathologies such as cardiovascular

diseases? What is useful feedback for the patient or for the clinician? And finally, what are the limits of this approach? What is the view of physicians? The purpose of this book is to provide, from a technical point of view, a complete description of most of the elements which are part of such sys

tems, including the sensors and the hardware, the signal processing and data management procedures, the classification and stratification models, the standards and the regulations, focusing on the state of the art and identifying the new directions for innovative solutions. In this book, readers wil

l find the fundamental elements that must be taken into account when developing devices and systems in the field of p-health.

應用於13.56MHz無線能量傳輸增益之超穎材料微型化設計與驗證

為了解決Implantable的問題，作者許睿祐 這樣論述：

先前研究已開發出應用於植入式醫療器材無線充電效能增益之13.56MHz超穎材料(Metamaterial)，並證實此超穎材料能提升無線充電天線線圈在未對準或是距離太遠之能量傳輸效率。由於先前提出的超穎材料尺寸過大，無法成功應用於現實生活中的無線充電系統，例如：智慧型手機、無線滑鼠甚至是植入式醫療器材等。本研究論文則提出利用鎳鋅軟磁作為磁性材料增加超穎材料的電感值進而微縮其尺寸，將原先超穎材料邊長從8.5cm縮小至6.5cm並測試其對於天線線圈無線傳輸的效率增益性，由量測結果可發現，傳輸距離在2cm以上，當置入微型化之超穎材料後，天線能量傳輸效率將有提升，且當傳輸距離越大，增益效率會越大。當傳

輸距離到3.5cm時，傳輸效率甚至能從原先之4%上升至11%，有近乎3倍的效率增益；另外，在天線線圈有水平錯位或是傾斜角度時，傳輸效率也能因置入超穎材料而有更好的傳輸效率，且當未對準的情況越嚴重時，傳輸效率的增益會越大，因此本研究證實利用磁性材料可以有效微縮超穎材料，並能維持相同之傳輸效率增益的效果，研究成果將有助於未來應用於植入式醫療器材之無線充電系統。