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Pressure and Force Sensors

Selection Considerations

104

Honeywell 1MICRO SWITCH Sensing and Control 11-800-537-6945 USA 1F1-815-235-6847 International 11-800-737-3360 Canada

REFERENCE AND APPLICATION DATA

COMPATIBILITY

It is very important to insure compatibility

between the pressure or force sensor and

the application in which it is used. The

following should be considered before a

sensor selection is made: (1) material; (2)

chemicals; (3) concentration; (4) temper-

ature; (5) exposure time; (6) type of expo-

sure; (7) criteria for failure; and (8) general

information such as application environ-

ment, protection of the device, and other

foreign substances in the area.

In all cases, the customer is ultimately

responsible for assuring that the de-

vice/material is suitable for the applica-

tion.

ERRORS THAT AFFECT

SENSOR PERFORMANCE

When calculating the total error of a pres-

sure or force sensor, the following de-

fined errors should be used. To deter-

mine the degree of specific errors for the

pressure sensor you have selected, refer

to that sensor’s specification page in the

catalog.

NOTE: In specific customer applications

some of the published specifications can

be reduced or eliminated. For example, if

a sensor is used over half the specified

temperature range, then the specified

temperature error can be reduced by half.

If an auto zeroing technique is used, the

null offset and null shift errors can be

eliminated.

Null offset is the electrical output present

when the pressure or force on both sides

of the diaphragm is equal.

Span is the algebraic difference be-

tween the output end points. Normally

the end points are null and full scale.

Null temperature shift is the change in

null resulting from a change in temper-

ature. Null shift is not a predictable error

because it can shift up or down from unit

to unit. Change in temperature will cause

the entire output curve to shift up or down

along the voltage axis (Figure 1).

Sensitivity temperature shift is the

change in sensitivity due to change in

temperature. Change in temperature will

cause a change in the slope of the sensor

output curve (Figure 2).

Linearity error is the deviation of the sen-

sor output curve from a specified straight

line over a desired pressure range. One

method of computing linearity error is

least squares, which mathematically pro-

vides a best fit straight line (B.F.S.L.) to

the data points (Figure 3).

Figure 1

Null Shift Error

Figure 2

Sensitivity Shift Error

Figure 3

Best Fit Straight Line Linearity

Figure 4

Terminal Base Linearity

Another method is terminal base linearity

(T.B.L.) or end point linearity. T.B.L. is

determined by drawing a straight line (L1)

between the end data points on the out-

put curve. Next draw a perpendicular line

from line L1 to a data point on the output

curve. The data point is chosen to achieve

the maximum length of the perpendicular

line. The length of the perpendicular line

represents terminal base linearity error

(Figure 4).

Pressure and Force Sensors

Selection Considerations

Honeywell 1MICRO SWITCH Sensing and Control 11-800-537-6945 USA 1F1-815-235-6847 International 11-800-737-3360 Canada

105

REFERENCE AND APPLICATION DATA

Repeatability error is the deviation in

output readings for successive applica-

tions of any given input pressure or force

with other conditions remaining constant

(Figure 5).

Hysteresis error is usually expressed as

a combination of mechanical hysteresis

and temperature hysteresis. MICRO

SWITCH expresses hysteresis as a com-

bination of the two effects (Figure 6).

Mechanical hysteresis is the output de-

viation at a certain input pressure or force

when that input is approached first with

increasing pressure or force and then

with decreasing pressure or force.

Temperature hysteresis is the output

deviation at a certain input, before and

after a temperature cycle.

Ratiometricity implies the sensor output

is proportional to the supply voltage with

other conditions remaining constant. Ra-

tiometricity error is the change in this pro-

portion and is usually expressed as a per-

cent of Span.

CALCULATING ACCURACY OR

TOTAL ERROR

When choosing a pressure or force sen-

sor, the total error contribution is impor-

tant. The following methods take into ac-

count the individual errors and the unit-to-

unit interchangeability errors.

Two methods for calculating total error

are:

Root Sum Square (R.S.S.) using maxi-

mum values, and worst case error. R.S.S.

method gives the most realistic value for

accuracy. With the worst case error meth-

od, the chances of one sensor having all

errors at the maximum are very remote.

Example

An application requires 0-15 psig, 5°to 50°temperature range, 7VDC supply. A

142PC15G will be used for the example (see 142PC15G specifications on page 37).

1. Determine error values

Parameter Max. (% Span)

Null offset .05V x 100% J1.0%

Span error .05V x 100% J1.0%

Linearity 0.75%

Combined null/span shift

(Calculate at max. and min.

application temperature. Use

higher of the two numbers)

50°C – 25°Cx 1% shift J0.70%

63°C – 25°C

25°C – 5°Cx 1% shift J0.50%

25°C – (−18°C)

Repeatability & Hysteresis 0.30%

Stability for 1 year 1.0%

Ratiometricity error 1.0%

2. Calculate total error

The R.S.S. method: take the square root of the sum of the squares of the errors

determined in Step 1

R.S.S. max. J£1.02+1.02+0.752+0.72+0.32+1.02+1.02

R.S.S. max. error J2.3% span max.

Worst Case Error J1.0 +1.0 +0.75 +0.7 +0.3 +1.- +1.0

Worst Case Error J5.75% span absolute maximum.

Reference/Index