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Biomedical engineering course
What is a good course for biomedical engineering?

By the way, the so-called basic medical courses are only 2-3 courses, all of which are surveys. We learned that:

Diagnostic electronic technology, digital electronic technology, circuit principle, college physics, probability theory and mathematical statistics, linear algebra, advanced mathematics, data structure, discrete mathematics, C++, C language, computer foundation, mechanical drawing, human anatomy, physiology, introduction to clinical medicine, introduction to life science, diagnostic electronic technology, digital electronic technology, circuit principle. (Basic course)

College physics experiment, medical experiment, metalworking practice, electrician experiment, electronic experiment, digital electronic experiment, hospital practice, C++ practice, computer course design, medical software design, database course design, electronic practice and telemedicine practice. (experimental class)

Hospital network design, hospital application integration technology, medical information system analysis and design, telemedicine, medical informatics, microcomputer principle, database principle, operating system. (professional frontier)

That's all. This is my major, and these are the courses we will study. How bitter!

Ⅱ what courses of biomedical engineering,

Basic courses: advanced mathematics, linear algebra, probability theory and mathematical statistics, complex variable function and integral transformation, general physics, basic chemistry, organic chemistry, computer foundation, C language programming, engineering drawing.

Medical courses: human anatomy, physiology, biochemistry, cell biology

Specialized courses: circuit analysis, analog electronic technology, digital electronic technology, signal and system, microcomputer principle and interface technology, digital signal processing, medical image processing, medical image, biological modeling and simulation, single chip microcomputer principle, biomedical electronics, medical instruments, biomaterials, biomechanics and biophysics.

Ⅲ What courses are there in biomedical engineering?

Main courses: advanced mathematics, general physics, analog electronic technology, pulse digital electronic technology, medical sensor, digital signal processing, microcomputer principle and application, medical image processing, medical instrument principle, medical imaging instrument, inspection and analysis instrument.

And clinical engineering, normal human morphology, biochemistry, physiology, diagnostics, internal medicine, surgery, etc. Practical courses: electronic technology practice, cognitive practice, metalworking practice, physiological experiment, electronic technology comprehensive experiment, professional practice comprehensive training, production practice, thesis comprehensive training, etc.

(3) Extended reading of biomedical engineering course.

Training requirements:

1, master the basic principles and design methods of electronic technology;

2, master the basic theory of signal detection and signal processing and analysis;

3. Have basic knowledge of biomedicine;

4. Have the ability of microprocessor and computer application;

5, with the preliminary ability of biomedical engineering research and development;

6. Have a certain basic knowledge of humanities and social sciences;

7. Understand the development of biomedical engineering;

8, master the basic methods of literature retrieval and information query.

Ⅳ What courses are offered for biomedical engineering undergraduates, which are mainly related to majors?

In fact, this major is very boring and it is difficult to find a job. Even if you ask me, I will find out my report card for four years. I am in a technical college, and my main direction is signal processing. Every school has a different emphasis. Please refer to.

High probability line generation

Digital English for College Physics Circuits

biochemistry

Disease physiology

C programming language

Modular power

Single chip microcomputer engineering optics

virtual instrument

Signals and Systems

Mechanical painting

Medical imaging technology and system

Biomedical photonics

Biomedical digital signal processing

Digital image processing

(same as coupled) Two copies (flow chart)

Medical electronic instruments and systems

Ⅳ What are the compulsory courses for biomedical engineering?

An old senior in biomedical engineering has come to answer your question ~

Biomedical engineering (BME) combines the principles of physics, chemistry, mathematics, computer and engineering, and is engaged in the research of biology, medicine, behavior or hygiene; Studying the state changes at all levels of the human body system and using engineering technology to control this change is aimed at solving medical related problems, ensuring human health and serving the prevention, diagnosis, treatment and rehabilitation of diseases.

Main courses: advanced mathematics, general physics, analog electronic technology, pulse digital electronic technology, medical sensor, digital signal processing, microcomputer principle and application, medical image processing, medical instrument principle, medical imaging instrument, inspection and analysis instrument.

I hope my answer will help you a little ~

ⅵ What courses do you need for biomedical engineering undergraduates?

Advanced mathematics, circuit principle, analog electronic technology, digital electronic technology, mechanical design, signal and system, digital signal processing, sensor and biomedical measurement, single chip microcomputer, introduction to basic medicine, introduction to clinical medicine, medical instruments, intelligent medical instrument design and medical equipment maintenance technology.

ⅶ What are the main learning contents of biomedical engineering?

Biomechanics is to study the mechanical properties of biological tissues and organs and the relationship between mechanical properties and their functions with mechanical theories and methods. The research results of biomechanics are of great significance for understanding the mechanism of human injury and determining the treatment method, and can also provide basis for the design of artificial organs and tissues. Biomechanics includes biological rheology (hemorheology, soft tissue mechanics and bone mechanics), circulatory system dynamics and respiratory system dynamics. Biomechanics has developed rapidly in bone mechanics. Biocybernetics is to study the mechanism of various regulatory phenomena in organisms, and then control the physiological and pathological phenomena of organisms, so as to achieve the purpose of preventing and treating diseases. Its method is to quantitatively study the dynamic process of a certain structural level of an organism from a holistic perspective by using a comprehensive method. Biological effect is to study the possible harm and function of various factors in medical diagnosis and treatment. It should study the propagation and distribution of light, sound, electromagnetic radiation and nuclear radiation in the body, as well as its biological effect and mechanism. Biological materials are the material basis for making various artificial organs, and must meet the requirements of various organs for materials, including physical and mechanical properties such as strength, hardness, toughness, wear resistance, deflection and surface characteristics. Because most of these artificial organs are implanted in the body, they are required to have corrosion resistance, chemical stability, non-toxicity and compatibility with body tissues or blood. These materials include metals, nonmetals, composite materials and polymer materials. Light alloy materials are widely used. Medical imaging is one of the main means of clinical diagnosis of diseases, and it is also a key subject of development and scientific research in all countries of the world. Medical imaging equipment mainly uses X-rays, ultrasonic waves, radionuclide magnetic vibration and so on for imaging. X-ray imaging equipment mainly includes large X-ray unit, X-ray digital subtraction (DSA) equipment and computerized tomography (CT) equipment. Ultrasonic imaging equipment includes B-ultrasound examination, color ultrasonic Doppler examination and other equipment; Radionuclide imaging equipment mainly includes γ camera, single photon emission computed tomography device and positron emission computed tomography device. The magnetic imaging apparatus has a vibration tomography device; In addition, there are infrared imaging and emerging impedance imaging technology. Medical electronic instruments are the main equipment for collecting, analyzing and processing human physiological signals, such as ECG, EEG, EMG and multi-parameter monitors, which are developing towards miniaturization and intelligence. Biochemical detection instruments that understand biochemical processes through body fluids have gradually moved towards miniaturization and automation. The development of therapeutic instruments and equipment is slightly worse than that of diagnostic equipment. X-ray, γ-ray, radionuclide, ultrasonic, microwave and infrared instruments are mainly used. Large-scale such as linear accelerator, X-ray deep therapy machine, extracorporeal lithotriptor, artificial respiration machine, etc. Small, such as laser intracavity lithotriptor, laser acupuncture instrument and electric instrument. The conventional equipment in the operating room has developed from simple surgical instruments to various emergency treatment instruments such as high-frequency electrotome, laser scalpel, respiratory anesthesia machine, monitor, X-ray TV, and defibrillator. In order to improve the therapeutic effect, in modern medical technology, many therapeutic systems have both diagnostic instruments and therapeutic devices with diagnostic functions. For example, defibrillator ECG monitor is used to diagnose cardiac function and guide the selection of treatment parameters. Extracorporeal lithotripsy is equipped with X-ray and ultrasonic imaging equipment for positioning, while artificial pacemaker implanted in human body has the function of sensing ECG, so as to carry out adaptive pacing therapy. Interventional radiology is the fastest developing field in radiology, that is, diagnostic X-ray or ultrasonic imaging equipment and endoscope are used to diagnose, guide and locate during interventional therapy. It solves many difficult problems in diagnosis and treatment, and the treatment of diseases is less harmful. In the new era, one of the high technologies that countries are competing to develop is medical imaging technology, among which image processing, impedance imaging, magnetic resonance imaging, three-dimensional imaging technology, image archiving and communication system are the main ones. In imaging technology, biomagnetic imaging is a new subject, which images the current of human tissue by measuring the human magnetic field. At present, biomagnetic imaging has two aspects. That is, magnetocardiogram (which can be used to observe the electrical activity of myocardial fibers and reflect arrhythmia and myocardial ischemia well) and magnetoencephalography (which can be used to diagnose brain invasion of epilepsy, Alzheimer's disease and acquired immunodeficiency syndrome, and also to locate and quantify the damaged brain areas). Another high-tech that countries all over the world are competing to develop is signal processing and analysis technology, which includes the processing and analysis of ECG, EEG, nystagmus, language, heart sound breathing and other signals and graphics. There is also neural network research in the high-tech field, and scientists all over the world have set off a research boom for this. It is considered as a new frontier discipline that may cause a major breakthrough. It studies the thinking mechanism of human brain and applies its achievements to the development of intelligent computer technology. Using intelligent principle to solve various practical problems is the purpose of neural network research, and gratifying achievements have been made in this field. Biomedical engineering (BME) combines the principles of physics, chemistry, mathematics, computer and engineering, and is engaged in the research of biology, medicine, behavior or hygiene; Put forward basic concepts, generate knowledge from molecular level to organ level, develop innovative biological products, materials, processing methods, implants, instruments and informatics methods, and use them for the purposes of disease prevention, diagnosis and treatment, patient rehabilitation and health improvement.

ⅷ What is biomedical engineering?

In the course of biomedical engineering, select several modules:

1. General course module. It mainly includes politics, physical education, college English, college physics, advanced mathematics, computer foundation, C language programming and so on.

2. Basic medical course module. It mainly includes the introduction of basic medicine, including human anatomy, histology and embryology, physiology and biochemistry.

3. Professional basic course module. Including analog electronic technology, digital electronic technology, circuit analysis, electronic measurement and technology.

4. Specialized course module. It mainly includes the principle of ultrasonic diagnostic instrument, X-ray equipment, medical inspection instrument, medical electronic instrument, medical electrodynamics and so on.

5. Real basic module. Practical teaching includes military training, productive labor, social practice, scientific research training, graduation practice and design. Including military training and so on.

Main courses: advanced mathematics, general physics, analog electronic technology, pulse digital electronic technology, medical sensor, digital signal processing, microcomputer principle and application, medical image processing, medical instrument principle, medical imaging instrument, inspection and analysis instrument.

And clinical engineering, normal human morphology, biochemistry, physiology, diagnostics, internal medicine, surgery and other auxiliary courses. Practical courses: electronic technology practice, cognitive practice, metalworking practice, physiological experiment, electronic technology comprehensive experiment, professional practice comprehensive training, production practice, thesis comprehensive training, etc.

Nine, biomedical engineering major courses

Advanced mathematics, general physics, analog electronic technology, pulse digital electronic technology, medical sensor, digital signal processing, microcomputer principle and application, medical image processing, medical instrument principle, medical imaging instrument, inspection and analysis instrument, clinical engineering, normal human body.