What is a meter?
A meter is any device built to
accurately detect and display an electrical quantity in a
form readable by a human being. Usually this "readable form"
is visual: motion of a pointer on a scale, a series of
lights arranged to form a "bargraph," or some sort of
display composed of numerical figures. In the analysis and
testing of circuits, there are meters designed to accurately
measure the basic quantities of voltage, current, and
resistance. There are many other types of meters as well,
but this chapter primarily covers the design and operation
of the basic three.
Most modern meters are "digital" in design,
meaning that their readable display is in the form of
numerical digits. Older designs of meters are mechanical in
nature, using some kind of pointer device to show quantity
of measurement. In either case, the principles applied in
adapting a display unit to the measurement of (relatively)
large quantities of voltage, current, or resistance are the
same.
The display mechanism of a meter is often
referred to as a movement, borrowing from its
mechanical nature to move a pointer along a scale so
that a measured value may be read. Though modern digital
meters have no moving parts, the term "movement" may be
applied to the same basic device performing the display
function.
The design of digital "movements" is beyond
the scope of this chapter, but mechanical meter movement
designs are very understandable. Most mechanical movements
are based on the principle of electromagnetism: that
electric current through a conductor produces a magnetic
field perpendicular to the axis of electron flow. The
greater the electric current, the stronger the magnetic
field produced. If the magnetic field formed by the
conductor is allowed to interact with another magnetic
field, a physical force will be generated between the two
sources of fields. If one of these sources is free to move
with respect to the other, it will do so as current is
conducted through the wire, the motion (usually against the
resistance of a spring) being proportional to strength of
current.
The first meter movements built were known
as galvanometers, and were usually designed with
maximum sensitivity in mind. A very simple galvanometer may
be made from a magnetized needle (such as the needle from a
magnetic compass) suspended from a string, and positioned
within a coil of wire. Current through the wire coil will
produce a magnetic field which will deflect the needle from
pointing in the direction of earth's magnetic field. An
antique string galvanometer is shown in the following
photograph:
Such instruments were useful in their time,
but have little place in the modern world except as
proof-of-concept and elementary experimental devices. They
are highly susceptible to motion of any kind, and to any
disturbances in the natural magnetic field of the earth.
Now, the term "galvanometer" usually refers to any design of
electromagnetic meter movement built for exceptional
sensitivity, and not necessarily a crude device such as that
shown in the photograph. Practical electromagnetic meter
movements can be made now where a pivoting wire coil is
suspended in a strong magnetic field, shielded from the
majority of outside influences. Such an instrument design is
generally known as a permanent-magnet, moving coil,
or PMMC movement:
In the picture above, the meter movement
"needle" is shown pointing somewhere around 35 percent of
full-scale, zero being full to the left of the arc and
full-scale being completely to the right of the arc. An
increase in measured current will drive the needle to point
further to the right and a decrease will cause the needle to
drop back down toward its resting point on the left. The arc
on the meter display is labeled with numbers to indicate the
value of the quantity being measured, whatever that quantity
is. In other words, if it takes 50 microamps of current to
drive the needle fully to the right (making this a "50 �A
full-scale movement"), the scale would have 0 �A written at
the very left end and 50 �A at the very right, 25 �A being
marked in the middle of the scale. In all likelihood, the
scale would be divided into much smaller graduating marks,
probably every 5 or 1 �A, to allow whoever is viewing the
movement to infer a more precise reading from the needle's
position.
The meter movement will have a pair of metal
connection terminals on the back for current to enter and
exit. Most meter movements are polarity-sensitive, one
direction of current driving the needle to the right and the
other driving it to the left. Some meter movements have a
needle that is spring-centered in the middle of the scale
sweep instead of to the left, thus enabling measurements of
either polarity:
Common polarity-sensitive movements include
the D'Arsonval and Weston designs, both PMMC-type
instruments. Current in one direction through the wire will
produce a clockwise torque on the needle mechanism, while
current the other direction will produce a counter-clockwise
torque.
Some meter movements are polarity-insensitive,
relying on the attraction of an unmagnetized, movable iron
vane toward a stationary, current-carrying wire to deflect
the needle. Such meters are ideally suited for the
measurement of alternating current (AC). A
polarity-sensitive movement would just vibrate back and
forth uselessly if connected to a source of AC.
While most mechanical meter movements are
based on electromagnetism (electron flow through a conductor
creating a perpendicular magnetic field), a few are based on
electrostatics: that is, the attractive or repulsive force
generated by electric charges across space. This is the same
phenomenon exhibited by certain materials (such as wax and
wool) when rubbed together. If a voltage is applied between
two conductive surfaces across an air gap, there will be a
physical force attracting the two surfaces together capable
of moving some kind of indicating mechanism. That physical
force is directly proportional to the voltage applied
between the plates, and inversely proportional to the square
of the distance between the plates. The force is also
irrespective of polarity, making this a polarity-insensitive
type of meter movement:
Unfortunately, the force generated by the
electrostatic attraction is very small for common
voltages. In fact, it is so small that such meter movement
designs are impractical for use in general test instruments.
Typically, electrostatic meter movements are used for
measuring very high voltages (many thousands of volts). One
great advantage of the electrostatic meter movement,
however, is the fact that it has extremely high resistance,
whereas electromagnetic movements (which depend on the flow
of electrons through wire to generate a magnetic field) are
much lower in resistance. As we will see in greater detail
to come, greater resistance (resulting in less current drawn
from the circuit under test) makes for a better voltmeter.
A much more common application of
electrostatic voltage measurement is seen in an device known
as a Cathode Ray Tube, or CRT. These are
special glass tubes, very similar to television viewscreen
tubes. In the cathode ray tube, a beam of electrons
traveling in a vacuum are deflected from their course by
voltage between pairs of metal plates on either side of the
beam. Because electrons are negatively charged, they tend to
be repelled by the negative plate and attracted to the
positive plate. A reversal of voltage polarity across the
two plates will result in a deflection of the electron beam
in the opposite direction, making this type of meter
"movement" polarity-sensitive:
The electrons, having much less mass than
metal plates, are moved by this electrostatic force very
quickly and readily. Their deflected path can be traced as
the electrons impinge on the glass end of the tube where
they strike a coating of phosphorus chemical, emitting a
glow of light seen outside of the tube. The greater the
voltage between the deflection plates, the further the
electron beam will be "bent" from its straight path, and the
further the glowing spot will be seen from center on the end
of the tube.
A photograph of a CRT is shown here:
In a real CRT, as shown in the above
photograph, there are two pairs of deflection plates rather
than just one. In order to be able to sweep the electron
beam around the whole area of the screen rather than just in
a straight line, the beam must be deflected in more than one
dimension.
Although these tubes are able to accurately
register small voltages, they are bulky and require
electrical power to operate (unlike electromagnetic meter
movements, which are more compact and actuated by the power
of the measured signal current going through them). They are
also much more fragile than other types of electrical
metering devices. Usually, cathode ray tubes are used in
conjunction with precise external circuits to form a larger
piece of test equipment known as an oscilloscope,
which has the ability to display a graph of voltage over
time, a tremendously useful tool for certain types of
circuits where voltage and/or current levels are dynamically
changing.
Whatever the type of meter or size of meter
movement, there will be a rated value of voltage or current
necessary to give full-scale indication. In electromagnetic
movements, this will be the "full-scale deflection current"
necessary to rotate the needle so that it points to the
exact end of the indicating scale. In electrostatic
movements, the full-scale rating will be expressed as the
value of voltage resulting in the maximum deflection of the
needle actuated by the plates, or the value of voltage in a
cathode-ray tube which deflects the electron beam to the
edge of the indicating screen. In digital "movements," it is
the amount of voltage resulting in a "full-count" indication
on the numerical display: when the digits cannot display a
larger quantity.
The task of the meter designer is to take a
given meter movement and design the necessary external
circuitry for full-scale indication at some specified amount
of voltage or current. Most meter movements (electrostatic
movements excepted) are quite sensitive, giving full-scale
indication at only a small fraction of a volt or an amp.
This is impractical for most tasks of voltage and current
measurement. What the technician often requires is a meter
capable of measuring high voltages and currents.
By making the sensitive meter movement part
of a voltage or current divider circuit, the movement's
useful measurement range may be extended to measure far
greater levels than what could be indicated by the movement
alone. Precision resistors are used to create the divider
circuits necessary to divide voltage or current
appropriately. One of the lessons you will learn in this
chapter is how to design these divider circuits.
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REVIEW:
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A "movement" is the display
mechanism of a meter.
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Electromagnetic movements work on the
principle of a magnetic field being generated by electric
current through a wire. Examples of electromagnetic meter
movements include the D'Arsonval, Weston, and iron-vane
designs.
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Electrostatic movements work on the
principle of physical force generated by an electric field
between two plates.
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Cathode Ray Tubes (CRT's) use an
electrostatic field to bend the path of an electron beam,
providing indication of the beam's position by light
created when the beam strikes the end of the glass tube.
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