Bridge circuits
No text on electrical metering could be
called complete without a section on bridge circuits. These
ingenious circuits make use of a null-balance meter to
compare two voltages, just like the laboratory balance scale
compares two weights and indicates when they're equal.
Unlike the "potentiometer" circuit used to simply measure an
unknown voltage, bridge circuits can be used to measure all
kinds of electrical values, not the least of which being
resistance.
The standard bridge circuit, often called a
Wheatstone bridge, looks something like this:
When the voltage between point 1 and the
negative side of the battery is equal to the voltage between
point 2 and the negative side of the battery, the null
detector will indicate zero and the bridge is said to be
"balanced." The bridge's state of balance is solely
dependent on the ratios of Ra/Rb and R1/R2,
and is quite independent of the supply voltage (battery). To
measure resistance with a Wheatstone bridge, an unknown
resistance is connected in the place of Ra or Rb,
while the other three resistors are precision devices of
known value. Either of the other three resistors can be
replaced or adjusted until the bridge is balanced, and when
balance has been reached the unknown resistor value can be
determined from the ratios of the known resistances.
A requirement for this to be a measurement
system is to have a set of variable resistors available
whose resistances are precisely known, to serve as reference
standards. For example, if we connect a bridge circuit to
measure an unknown resistance Rx, we will have to
know the exact values of the other three resistors at
balance to determine the value of Rx:
Each of the four resistances in a bridge
circuit are referred to as arms. The resistor in
series with the unknown resistance Rx (this would
be Ra in the above schematic) is commonly called
the rheostat of the bridge, while the other two
resistors are called the ratio arms of the bridge.
Accurate and stable resistance standards,
thankfully, are not that difficult to construct. In fact,
they were some of the first electrical "standard" devices
made for scientific purposes. Here is a photograph of an
antique resistance standard unit:
This resistance standard shown here is
variable in discrete steps: the amount of resistance between
the connection terminals could be varied with the number and
pattern of removable copper plugs inserted into sockets.
Wheatstone bridges are considered a superior
means of resistance measurement to the series
battery-movement-resistor meter circuit discussed in the
last section. Unlike that circuit, with all its
nonlinearities (logarithmic scale) and associated
inaccuracies, the bridge circuit is linear (the mathematics
describing its operation are based on simple ratios and
proportions) and quite accurate.
Given standard resistances of sufficient
precision and a null detector device of sufficient
sensitivity, resistance measurement accuracies of at least
+/- 0.05% are attainable with a Wheatstone bridge. It is the
preferred method of resistance measurement in calibration
laboratories due to its high accuracy.
There are many variations of the basic
Wheatstone bridge circuit. Most DC bridges are used to
measure resistance, while bridges powered by alternating
current (AC) may be used to measure different electrical
quantities like inductance, capacitance, and frequency.
An interesting variation of the Wheatstone
bridge is the Kelvin Double bridge, used for
measuring very low resistances (typically less than 1/10 of
an ohm). Its schematic diagram is as such:
The low-value resistors are represented by
thick-line symbols, and the wires connecting them to the
voltage source (carrying high current) are likewise drawn
thickly in the schematic. This oddly-configured bridge is
perhaps best understood by beginning with a standard
Wheatstone bridge set up for measuring low resistance, and
evolving it step-by-step into its final form in an effort to
overcome certain problems encountered in the standard
Wheatstone configuration.
If we were to use a standard Wheatstone
bridge to measure low resistance, it would look something
like this:
When the null detector indicates zero
voltage, we know that the bridge is balanced and that the
ratios Ra/Rx and RM/RN
are mathematically equal to each other. Knowing the values
of Ra, RM, and RN therefore
provides us with the necessary data to solve for Rx
. . . almost.
We have a problem, in that the connections
and connecting wires between Ra and Rx
possess resistance as well, and this stray resistance may be
substantial compared to the low resistances of Ra
and Rx. These stray resistances will drop
substantial voltage, given the high current through them,
and thus will affect the null detector's indication and thus
the balance of the bridge:
Since we don't want to measure these stray
wire and connection resistances, but only measure Rx,
we must find some way to connect the null detector so that
it won't be influenced by voltage dropped across them. If we
connect the null detector and RM/RN
ratio arms directly across the ends of Ra and Rx,
this gets us closer to a practical solution:
Now the top two Ewire voltage
drops are of no effect to the null detector, and do not
influence the accuracy of Rx's resistance
measurement. However, the two remaining Ewire
voltage drops will cause problems, as the wire connecting
the lower end of Ra with the top end of Rx
is now shunting across those two voltage drops, and will
conduct substantial current, introducing stray voltage drops
along its own length as well.
Knowing that the left side of the null
detector must connect to the two near ends of Ra
and Rx in order to avoid introducing those Ewire
voltage drops into the null detector's loop, and that any
direct wire connecting those ends of Ra and Rx
will itself carry substantial current and create more stray
voltage drops, the only way out of this predicament is to
make the connecting path between the lower end of Ra
and the upper end of Rx substantially resistive:
We can manage the stray voltage drops
between Ra and Rx by sizing the two
new resistors so that their ratio from upper to lower is the
same ratio as the two ratio arms on the other side of the
null detector. This is why these resistors were labeled Rm
and Rn in the original Kelvin Double bridge
schematic: to signify their proportionality with RM
and RN:
With ratio Rm/Rn set
equal to ratio RM/RN, rheostat arm
resistor Ra is adjusted until the null detector
indicates balance, and then we can say that Ra/Rx
is equal to RM/RN, or simply find Rx
by the following equation:
The actual balance equation of the Kelvin
Double bridge is as follows (Rwire is the
resistance of the thick, connecting wire between the
low-resistance standard Ra and the test
resistance Rx):
So long as the ratio between RM
and RN is equal to the ratio between Rm
and Rn, the balance equation is no more complex
than that of a regular Wheatstone bridge, with Rx/Ra
equal to RN/RM, because the last term
in the equation will be zero, canceling the effects of all
resistances except Rx, Ra, RM,
and RN.
In many Kelvin Double bridge circuits, RM=Rm
and RN=Rn. However, the lower the
resistances of Rm and Rn, the more
sensitive the null detector will be, because there is less
resistance in series with it. Increased detector sensitivity
is good, because it allows smaller imbalances to be
detected, and thus a finer degree of bridge balance to be
attained. Therefore, some high-precision Kelvin Double
bridges use Rm and Rn values as low as
1/100 of their ratio arm counterparts (RM and RN,
respectively). Unfortunately, though, the lower the values
of Rm and Rn, the more current they
will carry, which will increase the effect of any junction
resistances present where Rm and Rn
connect to the ends of Ra and Rx. As
you can see, high instrument accuracy demands that all
error-producing factors be taken into account, and often the
best that can be achieved is a compromise minimizing two or
more different kinds of errors.
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REVIEW:
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Bridge circuits rely on sensitive
null-voltage meters to compare two voltages for equality.
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A Wheatstone bridge can be used to
measure resistance by comparing unknown resistor against
precision resistors of known value, much like a laboratory
scale measures an unknown weight by comparing it against
known standard weights.
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A Kelvin Double bridge is a variant
of the Wheatstone bridge used for measuring very low
resistances. Its additional complexity over the basic
Wheatstone design is necessary for avoiding errors
otherwise incurred by stray resistances along the current
path between the low-resistance standard and the
resistance being measured.
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