System Operations

Question 1

What are the 6 main components of the ultrasound system?

Answer 1

Transducer
Pulser and beam former
Receiver
Display
Storage
Master synchronizer

Question 2

What does the master synchronizer do?

Answer 2

It organizes and maintains the timing and interaction of the different components of the ultrasound system by use of communication

Question 3

What does the pulser do?

Answer 3

Creates and controls electrical signals that are sent to PZT crystals to create sound beams or pulses

Question 4

What is another term for the pulser?

Answer 4

Transmitter

Question 5

What does the transducer do?

Answer 5

Transmission: to transform electrical energy to acoustic
Reception: to transform acoustic energy back to electrical

Question 6

What does the receiver do?

Answer 6

Changes the electronic components from the transducer (that are created by reflected sound) and transforms them to a form suitable for display

Question 7

What does the display do?

Answer 7

Presents the processed data from the machine

Flat screen monitor, transparency, audio speaker

Question 8

What does the storage do?

Answer 8

Stores or archives the ultrasound studies produced by that machine
Form of hard drive, CD or DVD, videotape, USB

Question 9

What determines the transducer output magnitude?

Answer 9

It is determined by the excitation voltage that comes from the transducer
Increased voltage means increased magnitude of PZT vibration

Question 10

What are other terms used to describe transducer output?

Answer 10

Output gain
Acoustic power
Pulser power
Energy output
Transmitter output
Power
Gain

Question 11

How is the image affected when the transducer output changes?

Answer 11

When there is lower output, the entire image is darker

When there is higher output, the entire image is brighter

Question 12

What is ultrasound “signal”?

Answer 12

The meaningful portion of the data that we want to have

Question 13

What is ultrasound “noise”?

Answer 13

The inaccurate portion of the data that has random or persistent disturbance, reducing the signal clarity
Signal contamination

Question 14

What is signal to noise ratio?

Answer 14

The comparison of the meaningful information to the amount of contamination

Question 15

Is a high or low signal to noise ratio desirable?

Answer 15

High S/N ratio

This means that the signal is stronger than the noise, producing a high quality image

Question 16

What is the primary method for improving S/N ratio?

Answer 16

Increasing output power

Improves image quality as signal dominates noise

Question 17

What component of the US system determines the PRP (and PRF)?

Answer 17

The pulser

Question 18

What is the beam former?

Answer 18

Transmission: creates and distributes the delay patterns for array transducers
Reception: dynamic receive focusing to establish correct time delays

Question 19

What is adopization?

Answer 19

A process of adjustments to the electrical spike voltages to reduce lobe artifact

Question 20

What is the receiver?

Answer 20

The electronic components of the machine that boosts the strength of the electric signals and converts them for display on the monitor?

Question 21

What is the order of functions performed by the receiver?

Answer 21

Amplification
Compensation
Compression
Demodulation
Reject

Question 22

What is amplification?

Answer 22

Increases the strength of all electronic signals equally

Needed when electronic signals are too low

Question 23

What is the synonym for receiver gain?

Answer 23

Amplification

Question 24

How does receiver gain affect the received signals?

Answer 24

It increases the strength of all signals identically

Question 25

How does receiver gain affect the entire image?

Answer 25

It makes the entire image brighter or darker

Question 26

Does the receiver gain create an image of uniform brightness top to bottom?

Answer 26

No, because it affects signals equally

Question 27

What is the preamplifier?

Answer 27

The process of improving the signal quality before it is amplified and occurs as close to the PZT as possible

Question 28

What is the purpose of compensation?

Answer 28

To create an image with uniform brightness from top to bottom

Question 29

What are other terms used to describe compensation?

Answer 29

Time gain compensation (TGC)
Depth compensation (DGC)
Swept gain

Question 30

Do higher or lower frequencies require more or less compensation?

Answer 30

Higher frequencies

They attenuate more quickly and need compensation at shallower depths

Question 31

What does compression do?

Answer 31

It reduces the total range of signals
It keeps the signals within accuracy range for system
It keeps the gray scale within human eye

Question 32

What are other terms used to describe compression?

Answer 32

Log compression

Dynamic range

Question 33

What is demodulation?

Answer 33

A two-part process that changes the signal to a form suitable for display
Rectification turns the negative voltages positive
Smoothing evens out the bumps by wrapping an envelope around them

Question 34

What does reject do?

Answer 34

It eliminates the low-level noise in images

Displays only meaningful low-level signals

Question 35

What signals are affected by reject?

Answer 35

All low-level echoes

No bright echoes

Question 36

What effect does reject have on an image?

Answer 36

It affects all low level echoes equally while not changing the bright echoes, causing weaker reflections to be eliminated from display

Question 37

How does output power affect the brightness of an image?

Answer 37

By altering the strength of the sound pulse that the transducer sends into the body
When the pulse is more powerful, the entire image becomes brighter

Question 38

How does receiver gain affect the brightness of an image?

Answer 38

It alters the strength of the voltages in the receiver created by the transducer during transmission
Higher amplification creates a brighter image
Lower amplification creates a darker image

Question 39

If an image is too bright should power or gain be reduced first?

Answer 39

Output power because it decreases patient exposure

ALARA

Question 40

If an image is too dark should power or gain be increased first?

Answer 40

Gain because it does not increase patient exposure

ALARA

Question 41

If you have insufficient penetration should you increase power or use a lower frequency transducer?

Answer 41

Use a lower frequency transducer because increasing power would alter patient exposure

Question 42

What is bistable?

Answer 42

Images that are only composed of black or white shades

Question 43

What is gray scale?

Answer 43

Images that are composed of many shades of gray to show multiple levels of contrast

Question 44

What is contrast?

Answer 44

The range of brilliances in the displayed image

Bistable are high contrast images

Question 45

What is brightness?

Answer 45

It determines the specific brilliance of the image

Question 46

What does the scan converter do?

Answer 46

It changes the format of stored data from spoke format to display format (horizontal lines)

Question 47

What are analog numbers?

Answer 47

Real world numbers that we use in our everyday lives
Continuous range of values
Not rounded

Question 48

What are digital numbers?

Answer 48

Numbers that are associated with computer devices
Can only have discrete values
Rounded

Question 49

What is spatial resolution?

Answer 49

Image detail

Great spatial resolution in analog scan converters

Question 50

What does the digital scan convertor do?

Answer 50

It uses the technology of the computer to convert images to numbers (digitizing)

Question 51

What is computer memory called?

Answer 51

Random Access Memory

RAM

Question 52

What is a pixel?

Answer 52

The smallest building block or element of a digital picture

Individual square boxes on the grid

Question 53

How are pixels related to spatial resolution?

Answer 53

Smaller pixels create higher pixel density, which improves spatial resolution

Question 54

What is a bit?

Answer 54

The smallest amount of digital storage of a computer’s memory

Question 55

What is a byte?

Answer 55

A group of 8 bits of computer memory

In the form of 1s and 0s

Question 56

How are the number of bits per pixel related to contrast resolution?

Answer 56

Fewer bits per pixel causes degraded contrast resolution with fewer shades of gray
More bits per pixel causes improved contrast resolution with more shades of gray

Question 57

If you know the number of bits per pixel how can you determine how many shades of gray will be presented?

Answer 57

By multiplying the number 2 times itself the same number of times as the number of bits
4 bits = 2x2x2x2 = 16 shades

Question 58

What does the analog-to-digital converter do?

Answer 58

It converts the electrical signals made by the transducer during reception from analog to digital

Question 59

What is preprocessing and when does it occur?

Answer 59

It is the processing of reflected signals that occurs before storage

Question 60

What is post-processing and when does it occur?

Answer 60

It is the processing of reflected signals that occurs after storage and in the digital scan converter

Question 61

What is read magnification and is it pre or post processing?

Answer 61

It is when the system reads the original stored image data and displays only the original data
Post processing

Question 62

What is write magnification and is it pre or post processing?

Answer 62

It is when the system rescans the area of interest and writes or provides new data to the scan converter
Preprocessing

Question 63

How does the magnification affect spatial resolution?

Answer 63

Improves spatial resolution because it has an increased number of pixels in the area of interest

Question 64

How does write magnification affect temporal resolution?

Answer 64

Improves temporal resolution when the area of interest is shallower than the original depth of view

Question 65

Where does coded excitation take place?

Answer 65

In the pulser

Question 66

What does coded excitation improve?

Answer 66

Image quality
Higher S/N
Better axial, spatial, temporal res
Deeper penetration

Question 67

What is spatial compounding?

Answer 67

When scan lines are steered by the transducer to image structures with multiple pulses from different angles

Question 68

What transducers perform spatial compounding?

Answer 68

Phased array transducers because electronic steering is necessary

Question 69

What are the benefits of spatial compounding?

Answer 69

Averages the frames by
Improving S/N ratio
Reducing speckle and clutter artifacts and shadowing

Question 70

What is frequency compounding?

Answer 70

When frequency ranges are divided into sub-bands are combined to make a single image

Question 71

What are the benefits of frequency compounding?

Answer 71

Reduces speckle artifact and noise

Question 72

What does edge enhancement do?

Answer 72

Increases the image contrast immediately around the edge of an area
Makes the image sharper with better defined boundaries

Question 73

What is temporal compounding?

Answer 73

When previous frames are superimposed over the most recent frame to create an image made of displayed information from past images

Question 74

What are synonyms for temporal compounding?

Answer 74

Persistence

Temporal averaging

Question 75

How does temporal compounding affect temporal resolution?

Answer 75

It reduces temporal resolution because it causes reduced frame rate

Question 76

What are the benefits of temporal compounding?

Answer 76

It creates a smooth image with
Higher S/N
Reduced noise
Improved image quality

Question 77

What is fill-in interpolation?

Answer 77

A method of filling in the gaps or missing data between scan lines

Question 78

Is fill-in interpolation pre or post-processing?

Answer 78

Preprocessing

Question 79

What is elastography?

Answer 79

A technique used to create an image based on the tissue’s mechanical properties

Question 80

What is dynamic range?

Answer 80

A method of describing the extent of signal variation that can occur while still maintaining accuracy