Basic theory of accelerometer, gyroscope and magnetometer. Newton’s law
of Classical Mech. Inertial and non inertial reference system: centrifugal,
Coriolis and Euler forces. IMU hardware description. Static IMU’s Noise
evaluation: mean and std deviation in all axis w.r.t. data sheet. Drift effect
in MATLAB. Sit-to-stand experiment with 2 IMUs: development of an
algorithm able to estimate the duration of stand-up, sit-down and variation
of the bending angles.
This document provides an overview of transducers for biomedical applications. It defines transducers as devices that convert one form of energy into another for measurement purposes. It classifies transducers as active or passive, analog or digital, and primary or secondary. It also discusses various transducer principles including capacitive, inductive, resistive, and piezoelectric. The document then focuses on specific biomedical applications, describing transducers used to measure electrical activity, blood pressure, blood flow, temperature, respiration, and pulse. Common transducer types for these applications include electrodes, strain gauges, inductive sensors, capacitive sensors, thermistors, and fiber optic sensors.
Biomedical engineering is the application of engineering principles and design concepts to medicine and biology. It seeks to close the gap between engineering and medicine by designing products and procedures that solve medical problems, such as artificial organs, prostheses, medical instrumentation, and health systems. Biomedical engineers work with doctors and scientists to develop and apply technology including designing equipment to analyze blood samples, creating artificial hearts and skin grafts, and developing prosthetic hips and devices to repair bones.
Biomedical engineering and recent trendsHanzelah Khan
This document provides an overview of biomedical engineering, including its applications, classifications, sub-disciplines, recent trends, and career prospects. Biomedical engineering applies engineering principles to healthcare for purposes like diagnosis, monitoring, and therapy. It combines engineering with medical and biological sciences. Recent trends include advances in medical imaging, biomechanics, biomaterials, rehabilitation engineering, and bioinstrumentation. Biomedical engineering offers excellent job prospects and earning potential, with a projected 10-year job growth of 72 percent.
This document discusses 3D bioprinting and its potential applications. It begins with definitions of bioprinting and discusses its goals in tissue engineering. Current achievements are summarized, including the first 3D printed bladder in 2006 and liver in 2009. Requirements for organ bioprinting are outlined, including cell sources, scaffold materials, and bioprinting technologies. The document concludes that bioprinting has potential to help address the shortage of organs for transplantation.
This document provides an overview of biomedical engineering. It begins by defining biomedical engineering as the application of engineering principles, techniques and methods to solve medical and biological problems. It then discusses the diversity in related terminology and the roles of medical engineers, clinical engineers and bioengineers. The document outlines several branches of biomedical engineering including biomechanics, biomaterials, medical devices and clinical engineering. It concludes by discussing the relationships between biomedical engineering and other fields like medicine, physics, and various engineering disciplines.
This document provides an overview of biomedical instrumentation. It discusses how instrumentation is used to monitor and control process variables for measurement and control. Biomedical instrumentation specifically creates instruments to measure, record, and transmit data to and from the body. Some key types of biomedical instrumentation systems are direct/indirect, invasive/noninvasive, contact/remote for sensing and actuating in real-time or statically. Several important instruments are discussed in detail, including X-rays, electrocardiography, magnetic resonance imaging, ultrasound, and computed tomography. The document outlines the basic workings, advantages, and disadvantages of these key biomedical instruments.
This document discusses 3D printing technology. It begins with a brief overview of how 3D printing works by building objects layer by layer from a digital file. It then provides a history of 3D printing, highlighting key developments. Examples are given of different uses for 3D printing, such as concept modeling, functional prototyping, manufacturing tools, end use parts, and more. Projections for significant growth in the 3D printing industry are mentioned. Notable 3D printer manufacturers and specific printer models are listed, along with potential future applications and scenarios involving 3D printing technology.
Basic theory of accelerometer, gyroscope and magnetometer. Newton’s law
of Classical Mech. Inertial and non inertial reference system: centrifugal,
Coriolis and Euler forces. IMU hardware description. Static IMU’s Noise
evaluation: mean and std deviation in all axis w.r.t. data sheet. Drift effect
in MATLAB. Sit-to-stand experiment with 2 IMUs: development of an
algorithm able to estimate the duration of stand-up, sit-down and variation
of the bending angles.
This document provides an overview of transducers for biomedical applications. It defines transducers as devices that convert one form of energy into another for measurement purposes. It classifies transducers as active or passive, analog or digital, and primary or secondary. It also discusses various transducer principles including capacitive, inductive, resistive, and piezoelectric. The document then focuses on specific biomedical applications, describing transducers used to measure electrical activity, blood pressure, blood flow, temperature, respiration, and pulse. Common transducer types for these applications include electrodes, strain gauges, inductive sensors, capacitive sensors, thermistors, and fiber optic sensors.
Biomedical engineering is the application of engineering principles and design concepts to medicine and biology. It seeks to close the gap between engineering and medicine by designing products and procedures that solve medical problems, such as artificial organs, prostheses, medical instrumentation, and health systems. Biomedical engineers work with doctors and scientists to develop and apply technology including designing equipment to analyze blood samples, creating artificial hearts and skin grafts, and developing prosthetic hips and devices to repair bones.
Biomedical engineering and recent trendsHanzelah Khan
This document provides an overview of biomedical engineering, including its applications, classifications, sub-disciplines, recent trends, and career prospects. Biomedical engineering applies engineering principles to healthcare for purposes like diagnosis, monitoring, and therapy. It combines engineering with medical and biological sciences. Recent trends include advances in medical imaging, biomechanics, biomaterials, rehabilitation engineering, and bioinstrumentation. Biomedical engineering offers excellent job prospects and earning potential, with a projected 10-year job growth of 72 percent.
This document discusses 3D bioprinting and its potential applications. It begins with definitions of bioprinting and discusses its goals in tissue engineering. Current achievements are summarized, including the first 3D printed bladder in 2006 and liver in 2009. Requirements for organ bioprinting are outlined, including cell sources, scaffold materials, and bioprinting technologies. The document concludes that bioprinting has potential to help address the shortage of organs for transplantation.
This document provides an overview of biomedical engineering. It begins by defining biomedical engineering as the application of engineering principles, techniques and methods to solve medical and biological problems. It then discusses the diversity in related terminology and the roles of medical engineers, clinical engineers and bioengineers. The document outlines several branches of biomedical engineering including biomechanics, biomaterials, medical devices and clinical engineering. It concludes by discussing the relationships between biomedical engineering and other fields like medicine, physics, and various engineering disciplines.
This document provides an overview of biomedical instrumentation. It discusses how instrumentation is used to monitor and control process variables for measurement and control. Biomedical instrumentation specifically creates instruments to measure, record, and transmit data to and from the body. Some key types of biomedical instrumentation systems are direct/indirect, invasive/noninvasive, contact/remote for sensing and actuating in real-time or statically. Several important instruments are discussed in detail, including X-rays, electrocardiography, magnetic resonance imaging, ultrasound, and computed tomography. The document outlines the basic workings, advantages, and disadvantages of these key biomedical instruments.
This document discusses 3D printing technology. It begins with a brief overview of how 3D printing works by building objects layer by layer from a digital file. It then provides a history of 3D printing, highlighting key developments. Examples are given of different uses for 3D printing, such as concept modeling, functional prototyping, manufacturing tools, end use parts, and more. Projections for significant growth in the 3D printing industry are mentioned. Notable 3D printer manufacturers and specific printer models are listed, along with potential future applications and scenarios involving 3D printing technology.
Презентация к лекции И. В. Артюхова "Цивилизационные и философские следствия развития современных технологий", состоявшейся в Центральном Доме ученых в Москве 24 марта 2009 г.
Международная научная конференция
«Социально-экономические трансформации под влиянием цифровизации»
Доклад: ИНДУСТРИЯ 4.0: БУДУЩЕЕ ИТ-СФЕРЫ
Авторы: Артамонова Елена Владимировна, Сафонов Александр Евгеньевич
В статье подробно описывается перспектива «выхода нанотехнологий из лабораторий» и развития инфраструктуры нанотехнологических исследований, что в конечном итоге положительно скажется на развитии наноиндустрии в России.
The remembrance of the resurrectables (2015) (1)Danila Medvedev
The 2015 spiritual service dedicated to cryonics patients in cryostasis in different organizations across the globe. The service remembers the people who were cryopreserved with a hope for their eventual resurrection.
Лекция Валерии Прайд 30 мая 2014 в "Светловке". Рассказ о том, полезно ли жить в городе, как можно сохранить здоровье, и что нужно сделать, чтобы продлить свою жизнь.
Утопология - как построить трансгуманистическую утопиюDanila Medvedev
Теория создания утопий от автора "Программы на будущее" (Россия-2). Что такое трансгуманистическая утопия, какие вообще бывают утопии, как строить утопию, что мы для этого делаем уже сейчас.
Невозможно победить РПЦ и остановить клерикализацию России, если не разбираться в менеджменте, стратегии и других подобных вещах.
Презентация с конференции "Светское государство - гарант общественного мира".
Название: "Стратегия борьбы с клерикализацией"
Автор: Данила Медведев
Создание альтернативных идеологических техноэкосистемDanila Medvedev
Выступление на конференции в Политехническом музее 5.9.2012.
Медведев Данила: Создание альтернативных идеологических техноэкосистем.
Об альтернативах венчурному рынку и государственному финансированию.
Выступление Данилы Медведева на конференции TEDx ГОРОД 2.0 27 мая 2011.
Тема: как избавить Москву от пробок с помощью Segway и другого персонального транспорта.
Видео выступления: http://www.youtube.com/watch?v=8ehhvfdrI00
KrioRus is a cryonics organization founded in 2005 in Russia. It has preserved 15 patients to date, using either neuropreservation or full-body cryopreservation techniques. The document describes 4 case studies to illustrate KrioRus's cryopreservation procedures. Case 1 involved an 80+ year old relative of a transhumanist who was cryopreserved over 20 hours after death. Case 2 was a 25 year old preserved in Moscow. Case 3 was a 70+ year old relative where perfusion was performed in a hospital morgue. Case 4 described an old dog that was cryopreserved in a private laboratory. KrioRus has facilities in Russia and can accept international clients to store patients cry
Management in the Russian Transhumanist MovementDanila Medvedev
The document summarizes the Russian Transhumanist Movement (RTM) and its projects. It discusses the importance of good management for transhumanism organizations. The RTM uses methods like seminars, lectures, and online communities to pursue projects in areas like aging research, cryonics, and molecular nanotechnology. It also outlines the enormous potential of transhumanism if emerging technologies can be developed and managed responsibly, as well as some potential challenges.
KrioRus is a cryonics organization founded in 2005 in Russia. It has preserved 15 patients so far using cryoprotectants like glycerol and cooling techniques like dry ice to cryopreserve bodies. Key staff include Valerija Pride as General Director and Igor Artyukhov as Science Director. The document describes four case studies of cryopreservation procedures on humans and one dog to illustrate KrioRus' process, which can involve delays, improvisation, and varying levels of success depending on the circumstances and logistics of each case. KrioRus is willing to cooperate internationally by accepting patients for storage from other countries and regions.
1. The document describes the Human Aging System Diagram (HASD) project, which aims to systematically organize knowledge about human aging processes and determine future directions for solving aging issues.
2. HASD is a multidisciplinary project between gerontology and cognitive science that uses a visual diagram to qualitatively describe the cause-and-effect relationships between aging processes, moving from primary causes to pathologies and death.
3. The diagram is developed through expert interviews with gerontologists and distributed work aided by visualization software, with the goal of providing sufficiently detailed aging process information to identify potential interventions.
4. Волны НТР 1941 1953 инфо био нано 1972 Z3 DNA 1981 STM когно CAT
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Editor's Notes
комментарий: если на плен. был Бахман про конвергенцию: «На плен. докл. был Бахман про конв. влияние на науку. Мы тоже просились на плен. долклад, но нас не пустили. Так что вы слушали “ чужеземца ”, а теперь послушайте нас».