EVAL-AD7747EBZ Analog Devices Inc, EVAL-AD7747EBZ Datasheet - Page 24
EVAL-AD7747EBZ
Manufacturer Part Number
EVAL-AD7747EBZ
Description
24-Bit Capacitance-to-Digital Converter Eval. Board
Manufacturer
Analog Devices Inc
Specifications of EVAL-AD7747EBZ
Silicon Manufacturer
Analog Devices
Application Sub Type
Capacitance-to-Digital Converter
Kit Application Type
Data Converter
Silicon Core Number
AD7747
Sensor Type
Touch, Capacitive
Interface
I²C
Voltage - Supply
2.7 V ~ 5.25 V
Embedded
No
Utilized Ic / Part
AD7747
Kit Contents
Board
Rohs Compliant
Yes
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Sensitivity
-
Sensing Range
-
Lead Free Status / RoHS Status
Lead free / RoHS Compliant, Lead free / RoHS Compliant
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
EVAL-AD7747EBZ
Manufacturer:
Analog Devices Inc
Quantity:
135
AD7747
CAPACITIVE SYSTEM OFFSET CALIBRATION
The capacitive offset is dominated by the parasitic offset in the
application, such as the initial capacitance of the sensor, any
parasitic capacitance of tracks on the board, and the capacitance
of any other connections between the sensor and the CDC.
Therefore, the AD7747 is not factory calibrated for capacitive
offset. It is the user’s responsibility to calibrate the system
capacitance offset in the application.
Any offset in the capacitance input larger than ±1 pF should
first be removed using the on-chip CAPDACs. The small offset
within ±1 pF can then be removed by using the capacitance
offset calibration register.
One method of adjusting the offset is to connect a zero-scale
capacitance to the input and execute the capacitance offset
calibration mode. The calibration sets the midpoint of the
±8.192 pF range (that is, Output Code 0x800000) to that
zero-scale input.
Another method is to calculate and write the offset calibration
register value; the LSB value is 31.25 aF (8.192 pF/2
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 AD7747 setup.
INTERNAL TEMPERATURE SENSOR
The temperature sensing method used in the AD7747 is to
measure a difference in ΔV
two different currents (see Figure 36). The ΔV
temperature is linear and can be expressed as
Δ
V
BE
=
I
(
n
f
Figure 36. Internal Temperature Sensor
)
ΔV
INTERNAL TEMPERATURE SENSOR
KT
BE
q
N × I
×
MODULATOR
ln(
GENERATOR
REFERENCE
24-BIT Σ-Δ
VOLTAGE
N
CLOCK
BE
)
voltage of a transistor operated at
VDD
SCALING
DIGITAL
FILTER
AND
DATA
BE
change with
17
).
Rev. 0 | Page 24 of 28
where:
K is Boltzmann’s constant (1.38 × 10
T is the absolute temperature in Kelvin.
q is the charge on the electron (1.6 × 10
N is the ratio of the two currents.
n
The AD7747 uses an on-chip transistor to measure the
temperature of the silicon chip inside the package. The Σ-Δ
ADC converts the ΔV
factory calibration coefficients. Thus, the output code is
proportional to temperature.
The AD7747 has a low power consumption resulting in only a
small effect due to the part self-heating (less than 0.5°C at
V
If the capacitive sensor can be considered to be at the same
temperature as the AD7747 chip, the internal temperature
sensor can be used as a system temperature sensor. That means
the complete system temperature drift compensation can be
based on the AD7747 internal temperature sensor without need
for any additional external components. See Figure 17 in the
Typical Performance Characteristics section.
EXTERNAL TEMPERATURE SENSOR
The AD7747 provides the option of using an external transistor
as a temperature sensor in the system. The ΔV
is similar to the internal temperature sensor method, is used.
However, it is modified to compensate for the serial resistance
of connections to the sensor. Total serial resistance (R
Figure 37) up to 100 Ω is compensated. The VIN(−) pin must
be grounded for proper external temperature sensor operation.
The AD7747 is factory calibrated for Transistor 2N3906 with
the ideality factor n
See Figure 18 in the Typical Performance Characteristics section.
f
DD
2N3906
is the ideality factor of the thermal diode.
TEMPERATURE
ΔV
= 5 V).
EXTERNAL
Temperatur
SENSOR
BE
Figure 37. Transistor as an External Temperature Sensor
R
R
S1
S2
VIN(+)
VIN(–)
e
( )
°
f
C
= 1.008.
BE
=
to digital; the data are scaled using
Code
2048
MODULATOR
−
GENERATOR
REFERENCE
24-BIT Σ-Δ
VOLTAGE
4096
CLOCK
VDD
−23
).
−19
coulombs).
SCALING
DIGITAL
FILTER
AND
BE
method, which
DATA
S1
+ R
S2
in
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