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FDC1004DSCT датащи(PDF) 11 Page - Texas Instruments

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номер детали FDC1004DSCT
подробное описание детали  4-Channel Capacitance-to-Digital Converter
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производитель  TI1 [Texas Instruments]
домашняя страница  http://www.ti.com
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FDC1004DSCT датащи(HTML) 11 Page - Texas Instruments

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FDC1004
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SNOSCY5B – AUGUST 2014 – REVISED APRIL 2015
Feature Description (continued)
In a single ended configuration, such as CINn vs. GND, SHLD1 is internally shorted to SHLD2. In a single ended
configuration, such as CINn vs. GND with CAPDAC enabled, SHLD1 is assigned to the selected channel,
SHLD2 is floating.
For best results, locate the FDC1004 as close as possible to the capacitive sensor. Minimize the connection
length between the sensor and FDC1004 CINn pins and between the sensor ground and the FDC1004 GND pin.
Shield the PCB traces to the CINn pins and connect the shielding to the FDC1004 SHLDx pins. In addition, if a
shielded cable is used to connect the FDC1004 to the sensor, the shield should be connected to the appropriate
SHLDx pin. In applications where only one SHLDx pin is used, the unused SHLDx pin can be left unconnected.
For more information on shielding, refer to Capacitive Sensing: Ins and Outs of Active Sensing application note
(SNOA926).
8.3.2 The CAPDAC
The FDC1004 full-scale input range is ±15 pF. The part can accept a higher capacitance on the input and the
common-mode or offset (constant component) capacitance can be balanced by the programmable on-chip
CAPDACs. The CAPDAC can be viewed as a negative capacitance connected internally to the CINn pin. The
relation between the input capacitance and output data can be expressed as DATA = (CINn – CAPDAC), n =
1...4. The CAPDACs have a 5-bit resolution, monotonic transfer function, are well matched to each other, and
have a defined temperature coefficient.
8.3.3 Capacitive System Offset Calibration
The capacitive offset can be due to many factors including the initial capacitance of the sensor, parasitic
capacitances of board traces, and the capacitance of any other connections between the sensor and the FDC.
The parasitic capacitances of the FDC1004 are calibrated out at production. If there are other sources of offset in
the system, it may be necessary to calibrate the system capacitance offset in the application. Any offset in the
capacitance input larger than ½ LSB of the CAPDAC should first be removed using the on-chip CAPDACs. Any
residual offset of approximately 1 pF can then be removed by using the capacitance offset calibration register.
The offset calibration register is reloaded by the default value at power-on or after reset. Therefore, if the offset
calibration is not repeated after each system power-up, the calibration coefficient value should be stored by the
host controller and reloaded as part of the FDC1004 setup.
8.3.4 Capacitive Gain Calibration
The gain is factory calibrated up to ±15 pF in the production for each part individually. The factory gain coefficient
is stored in a one-time programmable (OTP) memory.
The gain can be temporarily changed by setting the Gain Calibration Register (registers 0x11 to 0x14) for the
appropriate CINn pin, although the factory gain coefficient will be restored after power-up or reset.
The part is tested and specified for use only with the default factory calibration coefficient. Adjusting the Gain
calibration can be used to normalize the capacitance measurement of the CINn input channels.
8.4 Device Functional Modes
8.4.1 Single Ended Measurement
The FDC1004 can be used for interfacing to a single-ended capacitive sensor. In this configuration the sensor
should be connected to the input CINn (n = 1..4) pins of the FDC1004 and GND. The capacitance-to-digital
convertor (without using the CAPDAC, CAPDAC= 0pF) measures the positive (or the negative) input capacitance
in the range of 0 pF to 15 pF. The CAPDAC can be used for programmable shifting of the input range. In this
case it is possible to measure input capacitance in the range of 0 pF to ±15 pF which are on top of an offset
capacitance up to 100 pF. In single ended measurements with CAPDAC disabled SHLD1 is internally shorted to
SHLD2 (see Figure 10); if CAPDAC is enabled SHLD2 is floating (see Figure 11). The single ended mode is
enabled when the CHB register of the Measurements configuration registers (see Table 4) are set to b100 or
b111.
Copyright © 2014–2015, Texas Instruments Incorporated
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