MPR121QR2 Freescale Semiconductor, MPR121QR2 Datasheet - Page 13

MPR121QR2

Manufacturer Part Number

MPR121QR2

Description

IC CTLR TOUCH SENSOR 20-QFN

Manufacturer

Freescale Semiconductor

Type

Capacitive, Proximity Sensorr

Datasheet

1.MPR121QR2.pdf (57 pages)

Specifications of MPR121QR2

Number Of Inputs/keys

12 Key

Data Interface

I²C, Serial

Voltage - Supply

1.71 V ~ 3.6 V

Current - Supply

29µA

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

20-UQFN, 20-µQFN

Output Type

Logic

Interface

I²C

Input Type

Logic

Supply Voltage

2.5 V to 3.6 V

Dimensions

3 mm L x 3 mm W x 0.65 mm H

Temperature Range

- 40 C to + 85 C

Termination Style

SMD/SMT

Supply Current

29ÂµA

Ic Interface Type

I2C

Supply Voltage Range

1.71V To 3.6V

Sensor Case Style

QFN

No. Of Pins

Operating Temperature Range

-40Â°C To +85Â°C

Interface Type

I2C

Rohs Compliant

Yes

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

MPR121QR2
MPR121QR2TR

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

MPR121QR2

Manufacturer:

FREESCALE

Quantity:

20 000

Company:

Amily Shenzhen XNWY Technology Co., Ltd

Part Number:

MPR121QR2

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Sensors

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variation is of importance for an application after the current output, charge time and supply voltage are determined then the fol-

lowing equations can be used. The valid range for capacitance is calculated by using the minimum and maximum ADC values in

the capacitance equation. Substituting the low and high ADC equations into the capacitance equation yields the equations for

the minimum and maximum capacitance values which are

SENSITIVITY

and settings capacitance can be calculated,

following equation, representing the change in capacitance per one ADC count, where the ADC in the equation represents the

current value.

settings. The midpoint is assumed to be 512 for ADC and the nominal supply voltage of 1.8 V is used.

Table

range the equation is nonlinear, thus the sensitivity is best with the lowest capacitance. This graph shows the sensitivity derivative

reading across the valid range of capacitances for a set I, T, and V

21 pF) and a nominal 1.8 V supply.

Any ADC counts outside of the range shown are invalid and settings must be adjusted to be within this range. If capacitance

The sensitivity of the MPR121 is relative to the capacitance range being measured. Given the ADC value, current and time

For a given capacitance the sensitivity can be measured by taking the derivative of this equation. The result of this is the

This relationship is shown in the following graph by taking the midpoints off all possible ranges by varying the current and time

Smaller amounts of change indicate increased sensitivity for the capacitance sensor. Some sample values are shown in

In the previous cases, the capacitance is assumed to be in the middle of the range for specific settings. Within the capacitance

-0.5

-1.5

-2.5

-3.5

-4.5

-1

-2

-3

-4

-5

C low

Figure 7

Table 8.

500

Sensitivity vs. Midpoint Capacitance for V DD = 1.8 V

100

--------------- -

dADC

is representative of this effect.

------------------------- -

–

dC/dADC @cmid (pF/1 ADC Count)

-------------------------------

0.7

Midpoint Capacitance (pF)

---------------------------------- -

V DD

1000

Sensitivity (pF/ADC count)

and

Figure 6.

1024

ADC

C high

ADC

1024

-0.01953

-0.19531

. For simple small electrodes (that are approximately

1500

---------- -

0.7

2000

2500

Equation 5

Equation 6

Equation 7

MPR121

MPR121QR2 Freescale Semiconductor, MPR121QR2 Datasheet - Page 13

MPR121QR2

Specifications of MPR121QR2

Available stocks

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