Ultrasound Physics and Instrumentation (Part 1) PDF
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Uploaded by GloriousRhodochrosite
Dr. Ibrahim Hadadi
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Summary
This document provides an overview of ultrasound physics and instrumentation, covering its history, types, and applications, in the form of a presentation. It also explores the fundamental concepts of sound waves and their characteristics, including how sound waves travel through different mediums like solids, liquids, and gases.
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3-RAD6124 Ultrasound physics and instrumentation (part 1) Radiological Sciences Department By Dr. Ibrahim Hadadi The evolution of ultrasound technology World War I's naval warfare, Spallanzani's exploration led particularly the destruction Th...
3-RAD6124 Ultrasound physics and instrumentation (part 1) Radiological Sciences Department By Dr. Ibrahim Hadadi The evolution of ultrasound technology World War I's naval warfare, Spallanzani's exploration led particularly the destruction The medical industry began Dussik published the to the discovery of sound wrought by U-boats, experimenting with pioneering study on the beyond the audible spurred the advancement ultrasound for medical ultrasound examination of spectrum. of SONAR technology. purposes. the brain. 1880 1917 Late 1940s 1794 1912 1930s 1942 The Curie brothers, Pierre Utilizing piezoelectric Diagnostic uses for and Jacques, identified the principles, Langevin created ultrasound started to piezoelectric effect, an early ultrasound device. emerge, marking a new era foundational for later in medical imaging. ultrasound technology. The evolution of ultrasound technology Ultrasound technology Institutions worldwide The real-time B-scan expanded with the advent of developed pulsed ultrasound ultrasound was developed three-dimensional (3D) and technology, leading to 'B and introduced in obstetric four-dimensional (4D) Mode' imaging. imaging. imaging. 1956 1980s 1994 1950 1965 1990s Clinical adoption of Advancements made real- Steven Kapral and his team ultrasound commenced in time ultrasound imaging pioneered the use of B-mode Glasgow, paving the way for feasible. ultrasound for brachial plexus broader medical applications. blockade procedures What is sound? Sound is an energy form generated through vibration, a mechanical action that transmits energy from one location to another. It displays as a mechanical or longitudinal wave, requiring a medium—solid, liquid, or gas. Unlike electromagnetic waves, sound cannot propagate through a vacuum. Sound waves are characterized by alternating compressions and rarefactions. Compressions signify an increase in pressure or density, while rarefactions occurs during the troughs of the sound wave, where the vibrating source of the sound wave moves away from the molecules, causing them to become less densely packed. What is sound wave? A wave is characterized as a disturbance or fluctuation that transfers energy from one location to another within a medium. This transfer occurs without the need for physical contact between the points. We refer to mechanical waves as longitudinal waves. These are waves in which the displacement of the medium is in the same direction as the direction of the wave's propagation. Wave Formation When a vibration occurs, it disrupts the particles within a medium. This disturbance leads to the creation of waves that propagate through the medium Wave Formation All matter, including air, comprises molecules—tiny particles that are interconnected through elastic intermolecular forces. Classification of Waves Mechanical Waves: Defined by the disturbance of a physical medium. Examples include: Ocean waves Sound waves Seismic waves Electromagnetic Waves (transverse wave): These waves do not require a medium and can propagate through a vacuum. Examples include: Radio waves X-rays Light longitudinal vs. transverse wave Longitudinal Waves: Particle displacement occurs parallel to the wave's direction of energy movement. Transmission Mechanics: Requires an initial vibration from a source object. Requires a material for wave travel. The speed depends on the type and state of the medium. Transverse Waves: Particle displacement occurs perpendicular to the wave's direction of propagation. Transmission Mechanics: Velocity is relatively constant at approximately 299,792.456.2 m/s in a vacuum, which is the speed of light. Understanding Parameters in Acoustics Parameters can exhibit Directly Proportional: A parameter is a direct or inverse When one parameter quantifiable factor or proportional decreases, the other also characteristic. relationships. decreases. Inversely Proportional: In Key Parameters of Sound Waves: Important this relationship, a parameters to consider in sound waves include decrease in one parameter results in an Frequency, Period, Wavelength, Propagation increase in the other. Speed, Amplitude, Power, and Intensity