EI - Lecture 1 - Measurement Systems & Their Properties

elements of a measurement system

- measuring instrument - measurement system

inaccuracy definition

- the extent to which a reading might be wrong - usually given as a percentage of the full scale output (%f.s.o)

computer

- the last step includes recording, or presentation/display

precision

- the measure of precision is the standard deviation - good precision implies a small standard deviation

active instrument ex.

- The change in fluid level moves a potentiometer arm and the output signal consists of a proportion of the external voltage source applied across the two ends of the potentiometer. - The energy in the output signal comes from the external power source. - In this active instrument, primary transducer float system is merely modulating the value of the voltage from this external power source.

passive instrument ex.

- We want to measure the pressure of a fluid in a pipe. - The pressure of the fluid is translated into a movement of a pointer against a scale. - The energy expended in moving the pointer is derived entirely from the change in pressure measured. - In this passive instrument, there are no other energy inputs to the system.

piezoresistive effect

- a change in the electrical resistivity of a metal when mechanical strain (pressure/force/acceleration) is applied

accuracy ex.

- a force gauge of range 0-10N has a quoted inaccuracy of 1.0% f.s. then the maximum error to be expected in any reading is 0.1N - means that when the instrument is reading 1.0 N, the possible error is 10% of this value

precision definition

- a measurement system is highly precise if it gives the same value each time it is used to read a measurand - describes an instrument's degree of freedom from random errors

a linear system means...

- a proportional variation btwn the input and output - as a consequence, it avoids large variations in the output as a result of small variations in the input

range or span ex.

- a thermometer has a scale that reads from -40 degree C to 100 degee C - its range is -40 to 100 - its span is 140 deg C

classes of instruments: criteria that subdivide instruments into separate classes

- active and passive instruments - analog and digital instruments - indicating and instruments w/ signal output

active vs. passive instruments

- active: adjustments of the magnitude of the external energy input allows much greater control over measurement resolution compared to passive instruments - in terms of cost, passive instruments are cheaper to manufacture - choice btwn active and passive instruments for particular application involves carefully balancing the measurement resolution requirements against cost

what is a data logger?

- an electronic instrument that records measurements at set intervals over a period of time

electrical signal transmission

- analog voltage - simplest method via a shield wire/cable to reduce noise

analog meters

- are electromechanical devices that drive a point against a scale - ex. bathroom scale

low accuracy measurements from a high precision instrument

- are normally caused by a bias in the measurements, which is removable by recalibration

optical sensors

- based on the modulation of light travelling btwn a light source and a light detector - the transmitted light can travel along either an air path or a fibreoptic cable - light emitting diodes (LEDs) emit light in a narrow frequency band in the infrared region - air-path optical sensors are commonly used to measure proximity, translational motion and rotational motion

ex. analog instrument

- bathroom scale - as the input value (weight) changes, the point changes w/ a smooth continuous motion

precision repeatability and reproducibility

- both terms describe the spread of output readings for the same input

signal conditoning

- can include amplification, filtering, isolating - signal modification element

drift

- change in output of the transducer over time that is not a function of the measurand - usually determined in the absense of the signal at the input - doesn't depend on the input signal, but can depend on the external conditions - measurement systems are sensitive to temperature

instruments w/ signal type output

- commonly used in measurement system where the output measurement signal is recorded in some way for later use - usually, the measurement signal involved is an electrical voltage but it can take other forms in some systems such as an optical signal

thermometer: signal modification

- connecting the bulb to the stem to "amplify" the expansion of mercury

tolerance

- define the maximum error that is to be expected in measurement - not strictly speaking, a static characteristic - the accuracy of some instruments is sometimes quoted as a tolerance value - when used correctly, tolerance describes the maximum deviation of a manufactured component from some specified value

range or span

- define the minimum and maximum values of a quantity that the instrument is designed to measure

accuracy definition

- defined as the difference between the measurand value and true (correct) value

span

- defined as the range of an instrument from the minimum to maximum scale value - reported as one value - accuracy is defined as a percentage of time

measuring instrument

- describes a measurement system, whether it contains only one or many elements

high precision

- does not imply anything about measurement accuracy - a high precision instrument may have a low accuracy

drift ex.

- elasticity of a spring is temperature dependent

tolerance ex.

- electric circuit components such as resistors have tolerances of 5% - one resistor chosen at random from a batch having a nominal value 1000W and tolerance of 5% might have an actual value anywhere between 950W and 1050W

how can measured signals be transmitted?

- electrically - optically - radiotelemetry

evaluating linearity

- evaluation is based on the equation of a line that defines the relationship between the instrument output and the reference values

signal conditioning

- exists to improve the of a measurement system in some way

strain gauges

- experience a change in resistance when they are stretched or strained - able to detect very small displacements - bonded to the object whose displacement is to be measured

to determine the accuracy in terms of % full scale output

- find the worst point from comparing the difference btwn the measured and true values - assume the other points are at least that good

the degree of repeatability/reproducibility in measurements

- from an instrument - an alternative way of expressing its precision

transducer definition

- gives an output that is a function of the measurand (the input applied to it) - transforms energy from one form to another

analog instrument

- gives an output that varies continuously as the quantity being measured changes - the output can have an infinite number of values w/in the range that the instrument is designed to measure

digital instruments

- has an output that varies in discrete steps and so can only have a finite number of values - a computer performs its computations in digital form

potentiometer

- have a resistive element inside a long strip w/ a terminal at each end - wiper travels along the resistive strip when the knob is turned - the closer the wiper is to the end terminal it is wired in conjunction w/, the less the resistance b/c the path of the current will be shorter - the further away it moves from the terminal, the greater the resistance will be

what is one major drawback with indicating devices?

- human intervention is required to read and record a measurement - this process is particularly prone to error in the case of analogue output displays

ADC

- if a signal needs to be digitized, analog-to-digital conversion is needed

reproducibility

- if the measurement conditions vary

ex. solution

- if these values are plotted on a graph, the straight line relationship btwn voltage changes and temperature change is obvious - for a change in temperature of 30 degC, the change in volts of 7 - hence the measurement sensitivity = 7/30 = 0.233 volts/degC

ex. 2

- if we found the worst error btwn true and the indicated pressure is 0.5 psi we can calculate the %f.s. value by dividing the error value by the full scale output value (10 psi) - %F.S. = 0.5/10 = 5% - this means that at any point on the measurement scale there will or could be 5% error

importance of signal conditioning

- important where the primary transducer has a low output - ex. a thermocouple has an output of only a few millivolts and requires electronic amplification thus improving the sensitivity and resolution of measurement - other types of those that filter out electronic noise and remove bias etc.

how these subclasses are useful:

- in establishing several attributes of particular instruments such as > accuracy > cost > general applicability to different applications

transducer ex.

- in response to changes in its deformation under a given load, a strain gauge has a change in resistance which is changed to a voltage by a bridge circuit - in response to changes in temperature, a thermocouple outputs an electric voltage

analog meters are prone to errors from:

- inaccurate scale marking during manufacture, bearing friction, bent pointers and ambient temperature variations

indicating instruments

- include most passive ones - indicators can also be further divided into those that have an analogue output and those that have a digital display

where can you use a data logger?

- indoors, outdoors and underwater - can record data for up to months at a time, unattended

passive instrument

- instrument type in which the output entirely depends on the quantity to be measured

indicating vs. instruments w/ signal output

- instruments can also be classified as those that: > give an audio or visual indication of the magnitude of the physical quantity measured > give an output in the form of a measurement signal whose magnitude is proportional to the measured quantity

analog meters: human errors

- introduced through parallax error and mistakes in interpolating between scale markings - parallax error - quoted inaccuracy figures are between +/-0.1 and +3%

R^2

- lets us know what amount of variation in the values the regression line explains - if R^2 is 0.6 (60%) or more, the regression line is an adequate representation of the line of best fit

static characteristics of instruments

- linearity - sensitivity - accuracy - precision - range & span - resolution

piezoelectric transducer application

- many biomechanical applications include force & acceleration measurement

data logger size

- may fit into the palm of the hand - or it may be a multi-channel data collection instrument equipped w/ one or more external sensors

transducer

- measurand - the quantity to be measured (acceleration/force/light) - sensing element

linearity

- measurement systems w/ linear behaviour are desirable due to the linear relationship between input and output - only need 2 points to perform a calibration whereas non-linear systems require many

thermometer: sensing element

- mercury expands w/ increase in temperature

accuracy

- more usual to quote the inaccuracy figure - the manufacturer cannot guarentee the same error if the measurement system is used out of its range - important to choose a measurement system that has the best accuracy w/in the range of your expected value of the measurand

common measurement transducers

- piezoelectric transducers - piezoresistive transducers - strain gauges - potentiometer - optical sensors

potentiometer examples

- position sensor - used in kinematic measurement (electrogoniometer)

measurement system

- provides information about the physical value of some variables being measured

radiotelemetry signal transmission

- radio wireless transmission - data are transmitted in frequency modulated (FM) format

ADC + computer

- recorder / indicator / display element

static characteristics of an instrument

- related w/ a steady state response - these characteristics are quoted in specification or data sheets that are provided w/ equipment

analog meters continued...

- relatively simple and inexpensive - suffer less from noise - do not need a power supply

accuracy ex: how should instruments should be chosen?

- so that their range is appropriate to the spread of values being measured in order that the best possible accuracy is maintained in instrument readings

analog to digital conversion (ADC)

- takes a continuous signal (ex. voltage) and converts it into a discrete signal (1s and 0s) - needed for better recording, display and storage of data

computer (display, storage, recording): signal display or record

- takes the form either of a signal presentation unit or of a signal-recording unit

digitial meters continued...

- technically superior to analogue meters - have a greater cost due to the higher manufacturing costs - better measurement reliability and accuracy since the problem of analogue meter parallax error is eliminated - quoted inaccuracy figures are between +/-0.005% and +2%

piezoelectric effect

- the ability of certain materials to generate an electric charge in response to applied mechanical stress

digital meters

- the major part of a digital meter is the circuitry that converts the analog voltage being measured into a digital quantity - enables measurements to be recorded with much greater accuracy than that of an analog meter scale

range

- the measure of the instrument between the lowest and highest readings it can measure - reported as two values

sensitivity ex.

- the output volts of a thermocouple was measured at a range of temperatures - determine the measurement sensitivity of the thermometer in volts/degree Celsius

parallax error

- the perceived shift of an object's position as it is viewed from different angles

sensitivity

- the ratio between the change in the transducer signal and the corresponding change in the measured value - defined as the slope of the calibration curve - if the input/out relation is linear, the sensitivity is constant and all values of input

thermometer: indicator

- the reading scale

steady state response

- the relationship between the input and output when the input does not change - or the input is changing at a slow rate

full scale output

- the resulting output signal or displayed reading produced when the maximum measurement for a given device is applied

as strain is applied to the gauge...

- the shape of the cross-section of the resistance wire distorts, changing the cross-sectional area - as the resistance of the wire per unit length is inversely proportional to the cross sectional area, there is a consequential change in resistance

resolution

- the smallest interval between 2 distinguishable neighboring discrete values of the output signal - one of the major factors influencing resolution of an instrument is how finely its output scale is divided into subdivisions - the characteristic of the instrument is that it only can be changed via re-design

piezoresistive transducers

- transducers that are piezoresistive utilize the piezoresistive effect

optical signal transmission

- transmission of a signal as light - fibre-optic cable

active instrument

- type in which the quantity to be measured modules or adapts to magnitude of external power source

how does a data logger work?

- typically compact, battery-powered devices equipped w/ an internal microprocessor, data storage, and one or more sensors

piezoelectric transducers

- use the *piezoelectric effect to produce an output voltage

resolution ex.

- using a car speedometer, this has subdivisions of typically 5 km/h - means that when the needle is btwn the scale markings, we cannot estimate speed more accurately than to the nearest 5 km/h - thus 5km/h represents the resolution of the instrument

how to determine the goodness of fit

- using results of the regression eqn - calculating coefficient of determination - R^2

piezoelectric transducers continued...

- w/in the instrument electrodes are placed on the surface of the material under strain, surface charges can be measured as an output voltage - several materials have piezoelectric properties including quartz - the electric output of quartz is low and requires amplification to make the signal readable

accuracy ex.: if we were measuring forces w/ expected values btwn 0 and 1 N

- we would not use an instrument w/ a range of 0-10N

repeatability

- what a spread is called if the measurement conditions (ex. observer, location) are constant

when do the values quoted for instrument characteristics in such a data sheet apply?

- when the instrument is used under specified standard calibration conditions

2 groups of errors arising from measurement process

1) systematic errors 2) random errors

sensitivity is the ratio

scale deflection / value of measurand producing deflection

steps in the elements of a measurement system

transducer > signal conditioning > ADC > computer