MCP4021T-502E/SN Microchip Technology, MCP4021T-502E/SN Datasheet - Page 48

MCP4021T-502E/SN

Manufacturer Part Number

MCP4021T-502E/SN

Description

IC DGTL POT 5K 1CH 8SOIC

Manufacturer

Microchip Technology

Datasheets

1.MCP4022T-202ECH.pdf (2 pages)

2.MCP4022T-202ECH.pdf (64 pages)

3.MCP4021T-502ESN.pdf (62 pages)

Specifications of MCP4021T-502E/SN

Memory Type

Non-Volatile

Taps

Resistance (ohms)

Number Of Circuits

Temperature Coefficient

150 ppm/°C Typical

Interface

Up/Down

Voltage - Supply

2.7 V ~ 5.5 V

Operating Temperature

-40°C ~ 125°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (3.9mm Width)

Resistance In Ohms

End To End Resistance

5kohm

Resistance Tolerance

Â± 20%

No. Of Steps

Supply Voltage Range

2.7V To 5.5V

Control Interface

2 Wire, Serial

No. Of Pots

Single

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With

MCP4XXXDM-DB - BOARD DAUGHTER DIGIPOT MCP4XXXMCP402XEV - BOARD EVAL FOR MCP402X

Lead Free Status / RoHS Status

Lead free / RoHS Compliant, Lead free / RoHS Compliant

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MCP4021/2/3/4

8.3

Thermistors are resistors with very predictable

variation with temperature. Thermistors are a popular

sensor choice when a low-cost, temperature-sensing

solution is desired. Unfortunately, thermistors have

non-linear characteristics that are undesirable, typically

requiring trimming in an application to achieve greater

accuracy. There are several common solutions to trim

and linearize thermistors. Figure 8-6 and Figure 8-7

are simple methods for linearizing a 3-terminal NTC

thermistor. Both are simple voltage dividers using a

Positive Temperature Coefficient (PTC) resistor (R

with a transfer function capable of compensating for the

lineararity

Coefficient (NTC) thermistor.

The circuit, illustrated by Figure 8-6, utilizes a digital

rheostat for trimming the offset error caused by the

thermistor’s part-to-part variation. This solution puts the

digital potentiometer’s R

calculation. The MCP4021/2/3/4’s R

coefficient is 50 ppm (-20°C to +70°C). R

substantially greater than R

varies with V

50 k

cases, insignificant as long as the wiper setting is > 6.

For the 2 k

significant because it is a higher percentage of R

For these reasons, the circuit illustrated in Figure 8-6 is

not the most optimum method for “exciting” and

linearizing a thermistor.

FIGURE 8-6:

a Digital Potentiometer in a Rheostat

Configuration.

The circuit illustrated by Figure 8-7 utilizes a digital

potentiometer for trimming the offset error. This

solution removes R

with the error associated with R

but can be utilized to reduce the trimming “window” and

reduce variation due to the digital potentiometer’s R

part-to-part variability.

DS21945C-page 48

devices, the error introduced by R

Temperature Sensor Applications

error

devices, the error introduced by R

, wiper setting and temperature. For the

from the trimming equation along

Thermistor Calibration using

the

NTC

Thermistor

into the voltage divider

Negative

MCP4022

OUT

’s error because R

. R

is not required,

Temperature

temperature

is, in most

’s error is

)

FIGURE 8-7:

a Digital Potentiometer in a Potentiometer

Configuration.

8.4

Another common configuration to “excite” a sensor

(such as a strain gauge, pressure sensor or thermistor)

is the wheatstone bridge configuration. The wheat-

stone bridge provides a differential output instead of a

single-ended

wheatstone bridge utilizing one to three digital

potentiometers. The digital potentiometers in this

example are used to trim the offset and gain of the

wheatstone bridge.

FIGURE 8-8:

Trimming.

MCP4022

Wheatstone Bridge Trimming

50 k

MCP4022

output.

Thermistor Calibration using

Wheatstone Bridge

OUT

Figure 8-8

NTC

Thermistor

MCP4021

2.1 k

OUT

MCP4022

50 k

illustrates

MCP4021T-502E/SN Microchip Technology, MCP4021T-502E/SN Datasheet - Page 48

MCP4021T-502E/SN

Specifications of MCP4021T-502E/SN

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