AD AD7877ACPZ-REEL7 Touch screen controller Datasheet

Touch Screen Controller
AD7877
FEATURES
FUNCTIONAL BLOCK DIAGRAM
VCC
7
AD7877
X+ 12
X– 10
Y+ 13
Y– 11
X– Y– GND X+ Y+ VREF
DUAL 3-1
MUX
AUX1/GPIO1 6
AUX2/GPIO2 5
REF–
AUX3/GPIO3 4
BAT1 3
BATTERY
MONITOR
BAT2 2
REF+
CLOCK
12-BIT SUCCESSIVE
APPROXIMATION ADC
WITH TRACK-AND-HOLD
STOP
ACQ
LOGIC
20
STOPACQ
14
AGND
15
DGND
22
ALERT
21
GPIO4
17
PENIRQ
RESULTS
REGISTERS
BATTERY
MONITOR
LIMIT
COMPARATOR
LIMIT
REGISTERS
TEMPERATURE
SENSOR
VREF 31
ALERT STATUS/
MASK REGISTER
AOUT 30
ARNG 29
BUF
GPIO
REGISTERS
CONTROL
REGISTERS
DAC
REGISTER
8-BIT
DAC
CONTROL LOGIC AND SERIAL PORT
18
19
CS
DIN
23
ALERT
LOGIC
26
DAV DCLK
27
28
DOUT
VDRIVE
TO
GPIO1-3
PEN INTERRUPT
AND WAKE-UP
ON TOUCH
Figure 1.
GENERAL DESCRIPTION
The AD7877 is a 12-bit successive approximation ADC with a
synchronous serial interface and low on resistance switches for
driving touch screens. The AD7877 operates from a single 2.7 V
to 5.25 V power supply (functional operation to 2.2V), and
features throughput rates of 125 kSPS. The AD7877 features
direct battery measurement on two inputs, temperature and
touch-pressure measurement.
The AD7877 also has an on-board reference of 2.5 V. When not
in use, it can be shut down to conserve power. An external
reference can also be applied and can be varied from 1 V to
+VCC, while the analog input range is from 0 V to VREF. The
device includes a shutdown mode, which reduces its current
consumption to less than 1 µA.
To reduce the effects of noise from LCDs, the acquisition phase
of the on-board ADC can be controlled via the STOPACQ pin.
User-programmable conversion controls include variable
acquisition time and first conversion delay. Up to 16 averages
can be taken per conversion. There is also an on-board DAC for
LCD backlight or contrast control. The AD7877 can run in
either slave or master mode, using a conversion sequencer and
timer. It is ideal for battery-powered systems such as personal
digital assistants with resistive touch screens and other portable
equipment.
The part is available in a 32-lead lead frame chip scale package
(LFCSP).
Rev. A
Information furnished by Analog Devices is believed to be accurate and reliable.
However, no responsibility is assumed by Analog Devices for its use, nor for any
infringements of patents or other rights of third parties that may result from its use.
Specifications subject to change without notice. No license is granted by implication
or otherwise under any patent or patent rights of Analog Devices. Trademarks and
registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.326.8703
© 2004 Analog Devices, Inc. All rights reserved.
03796-001
Personal digital assistants
Smart hand-held devices
Touch screen monitors
Point-of-sale terminals
Medical devices
Cell phones
Pagers
IN
SEQUENCER
2.5V
REF
APPLICATIONS
9 TO 1
I/P
MUX
ADC DATA
4-wire touch screen interface
LCD noise reduction feature (STOPACQ pin)
Automatic conversion sequencer and timer
User-programmable conversion parameters
On-chip temperature sensor: −40°C to +85°C
On-chip 2.5 V reference
On-chip 8-bit DAC
3 auxiliary analog inputs
1 dedicated and 3 optional GPIOs
2 direct battery measurement channels (0.5 V to 5 V)
3 interrupt outputs
Touch-pressure measurement
Wake up on touch function
Specified throughput rate of 125 kSPS
Single supply, VCC of 2.7 V to 5.25 V
Separate VDRIVE level for serial interface
Shutdown mode: 1 µA maximum
32-lead LFCSP 5 mm x 5 mm package
AD7877
TABLE OF CONTENTS
Specifications..................................................................................... 3
Sequencer Registers ................................................................... 22
Timing Specifications....................................................................... 5
Interrupts..................................................................................... 24
Absolute Maximum Ratings............................................................ 6
Syncronizing the AD7877 to the Host CPU ........................... 25
ESD Caution.................................................................................. 6
8-Bit DAC ........................................................................................ 26
Pin Configuration and Function Descriptions............................. 7
Serial Interface ................................................................................ 28
Terminology ...................................................................................... 9
Writing Data ............................................................................... 28
Typical Performance Characteristics ........................................... 10
Write Timing............................................................................... 29
Circuit Information ........................................................................ 14
Reading Data............................................................................... 29
Touch Screen Principles ............................................................ 14
VDRIVE Pin..................................................................................... 29
Measuring Touch Screen Inputs ............................................... 15
General-Purpose I/O Pins............................................................. 30
Touch-Pressure Measurement .................................................. 16
GPIO Configuration .................................................................. 30
STOPACQ Pin ............................................................................ 16
Grounding and LayouT ................................................................. 32
Temperature Measurement ....................................................... 17
PCB Design Guidelines for Chip Scale Packages................... 32
Battery Measurement................................................................. 18
Register Maps.................................................................................. 33
Auxiliary Inputs .......................................................................... 19
Detailed Register Descriptions ..................................................... 35
Limit Comparison ...................................................................... 19
GPIO Registers ........................................................................... 41
Control Registers ............................................................................ 20
Outline Dimensions ....................................................................... 43
Control Register 1....................................................................... 20
Ordering Guide .......................................................................... 43
Control Register 2....................................................................... 21
REVISION HISTORY
11/04—Changed from Rev. 0 to Rev. A
Changes to Absolute Maximum Ratings ...................................... 6
Changes to Figure 4.......................................................................... 7
Changes to Table 4............................................................................ 7
Changes to Grounding and Layout section ................................ 32
Changes to Figure 42...................................................................... 32
Changes to Ordering Guide .......................................................... 43
7/04—Revision 0: Initial Version
Rev. A | Page 2 of 44
AD7877
SPECIFICATIONS
VCC = 2.7 V to 3.6 V, VREF = 2.5 V internal or external, fDCLK = 2 MHz, TA = −40°C to +85°C, unless otherwise noted.
Table 1.
Parameter
ADC
DC ACCURACY
Resolution
No Missing Codes
Integral Nonlinearity1
Differential Nonlinearity1
Offset Error1
Gain Error1
Noise
Power Supply Rejection
Internal Clock Ffrequency
SWITCH DRIVERS
On Resistance1
Y+, X+
Y−, X−
ANALOG INPUTS
Input Voltage Ranges
DC Leakage Current
Input Capacitance
Accuracy
REFERENCE INPUT/OUTPUT
Internal Reference Voltage
Internal Reference Tempco
VREF Input Voltage Range
DC Leakage Current
VREF Input Impedance
TEMPERATURE MEASUREMENT
Temperature Range
Resolution
Differential Method2
Single Conversion Method3
Accuracy
Differential Method2
Single Conversion Method3
BATTERY MONITOR
Input Voltage Range
Input Impedance
Accuracy
Min
Typ
12
11
12
Max
Unit
70
70
2
Bits
Bits
LSB
LSB
LSB
LSB
µV rms
dB
MHz
14
14
Ω
Ω
±2
0
±2
−0.99/+2
±6
±4
VREF
±0.1
30
0.3
2.44
2.55
±50
1
VCC
±1
1
−40
+85
V
µA
pF
%
V
ppm/°C
V
µA
GΩ
Test Conditions/Comments
LSB size = 610 µV
LSB size = 610 µV
VCC = 2.7 V
External reference
All channels, internal VREF
CS = GND or VCC; typically 25 Ω when on-board
reference enabled
°C
1.6
0.3
°C
°C
±4
±2
°C
°C
Calibrated at 25°C
V
kΩ
%
@VREF = 2.5 V
Sampling, 1 GΩ when battery monitor off
External/internal reference, see Figure 25
0.5
5
14
1
3.2
Rev. A | Page 3 of 44
AD7877
Parameter
DAC
Resolution
Integral Nonlinearity
Differential Nonlinearity
Voltage Mode
Output Voltage Range
Slew Rate
Output Settling Time
Capacitive Load Stability
Output Impedance
Short Circuit Current
Current Mode
Output Current Range
Output Impedance
LOGIC INPUTS
Input High Voltage, VINH
Input Low Voltage, VINL
Input Current, IIN
Input Capacitance, CIN4
LOGIC OUTPUTS
Output High Voltage, VOH
Output Low Voltage, VOL
Floating-State Leakage Current
Floating-State Output Capacitance4
Output Coding
CONVERSION RATE
Conversion Time
Throughput Rate
POWER REQUIREMENTS
VCC (Specified Performance)
VDRIVE
ICC
Converting Mode
Static
Shutdown Mode
Min
Typ
Max
Unit
Test Conditions/Comments
8
±1
±1
Bits
Bits
0 − VCC/2
0 − VCC
−0.4, +0.5
12
50
75
21
V
V
V/µs
µs
pF
kΩ
mA
DAC register Bit 2 = 0, Bit 0 = 0
DAC register Bit 2 = 0, Bit 0 = 1
µA
DAC register Bit 2 = 1, full-scale current is set by RRNG
Power-down mode
0
Guaranteed monotonic by design
15
100
1000
Open
0.7 VDRIVE
0.3 VDRIVE
±1
10
V
V
µA
pF
0.4
±10
10
V
V
µA
pF
VDRIVE − 0.2
0 to 3/4 scale, RLOAD = 10 kΩ, CLOAD = 50 pF
RLOAD = 10 kΩ
Power-down mode
Typically 10 nA, VIN = 0 V or VCC
ISOURCE = 250 µA, VCC/VDRIVE = 2.7 V to 5.25 V
ISINK = 250 µA
Straight (natural) binary
8
125
2.7
1.65
240
650
900
150
µs
kSPS
CS high to DAV low
3.6
VCC
V
V
Functional from 2.2 V to 5.25 V
380
900
µA
µA
µA
µA
1
µA
1
See the Terminology section.
Difference between Temp0 and Temp1 measurement. No calibration necessary.
Temperature drift is −2.1 mV/°C.
4
Sample tested @ 25°C to ensure compliance.
2
3
Rev. A | Page 4 of 44
Digital I/Ps = 0 V or VCC
ADC on, internal reference off, VCC = 3.6 V
ADC on, internal reference on, VCC = 3.6 V
ADC on, internal reference on, DAC on
ADC on, but not converting, internal reference off,
VCC = 3.6 V
AD7877
TIMING SPECIFICATIONS
TA = TMIN to TMAX, unless otherwise noted; VCC = 2.7 V to 5.25 V, VREF = 2.5 V. Sample tested at 25°C to ensure compliance. All input signals
are specified with tR = tF = 5 ns (10% to 90% of VCC) and timed from a voltage level of 1.6 V.
Table 2.
Parameter
fDCLK1
t1
t2
t3
t4
t5
t62
t72
t83
t9
Limit at TMIN, TMAX
10
20
16
20
20
12
12
16
16
16
0
Unit
kHz min
MHz max
ns min
ns min
ns min
ns min
ns min
ns max
ns max
ns max
ns min
Description
CS falling edge to first DCLK rising edge
DCLK high pulse width
DCLK low pulse width
DIN setup time
DIN hold time
CS falling edge to DOUT, three-state disabled
DCLK falling edge to DOUT valid
CS rising edge to DOUT high impedance
CS rising edge to DCLK ignored
1
Mark/space ratio for the DCLK input is 40/60 to 60/40.
Measured with the load circuit of Figure 3 and defined as the time required for the output to cross 0.4 V or 2.0 V.
3
t8 is derived from the measured time taken by the data outputs to change 0.5 V when loaded with the circuit of Figure 3. The measured number is then extrapolated
back to remove the effects of charging or discharging the 50 pF capacitor. This means that the time, t8, quoted in the timing characteristics is the true bus relinquish
time of the part and is independent of the bus loading.
2
CS
t1
t2
1
DCLK
2
t9
t3
3
15
16
t5
t4
MSB
t7
t6
DOUT
LSB
MSB
t8
LSB
Figure 2. Detailed Timing Diagram
Rev. A | Page 5 of 44
03796-004
DIN
AD7877
ABSOLUTE MAXIMUM RATINGS
TA = 25°C, unless otherwise noted.
Parameter
VCC to GND
Analog Input Voltage to GND
Digital Input Voltage to GND
Digital Output Voltage to GND
VREF to GND
Input Current to Any Pin Except Supplies1
ESD Rating
Operating Temperature Range
Storage Temperature Range
Junction Temperature
LFCSP Package
Power Dissipation
θJA Thermal Impedance
IR Reflow Peak Temperature
Pb-Free Parts Only
Lead Temperature (Soldering 10 s)
1
Rating
−0.3 V to +7 V
−0.3 V to VCC + 0.3 V
−0.3 V to VCC + 0.3 V
−0.3 V to VCC + 0.3 V
−0.3 V to VCC + 0.3 V
10 mA
2.5 kV
−40°C to +85°C
−65°C to +150°C
150°C
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only and functional operation of the device at these or
any other conditions above those listed in the operational
sections of this specification is not implied. Exposure to
absolute maximum rating conditions for extended periods may
affect device reliability.
450 mW
135.7°C/W
220°C
260°C (±0.5°C)
300°C
200µA
TO OUTPUT
PIN
IOL
1.6V
CL
50pF
200µA
IOH
03796-003
Table 3.
Figure 3. Load Circuit for Digital Output Timing Specifications
Transient currents of up to 100 mA do not cause SCR latch-up.
ESD CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on
the human body and test equipment and can discharge without detection. Although this product features
proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy
electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance
degradation or loss of functionality.
Rev. A | Page 6 of 44
AD7877
NC
VREF
AOUT
ARNG
VDRIVE
DOUT
DCLK
NC
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
32
31
30
29
28
27
26
25
24
NC
BAT2 2
23
DAV
BAT1 3
AD7877
22
ALERT
TOP VIEW
(Not to Scale)
21
GPIO4
20
STOPACQ
AUX1/GPIO1 6
19
DIN
VCC 7
18
CS
NC 8
17
PENIRQ
AUX3/GPIO3 4
11
12
13
14
15
16
X+
Y+
AGND
DGND
NC
NC = NO CONNECT
10
Y–
NC
9
X–
AUX2/GPIO2 5
03796-002
NC 1
Figure 4. Pin Configuration
Table 4. Pin Function Descriptions
Pin No.
1
2
3
4
5
6
7
8–9
10
11
12
13
14
Mnemonic
NC
BAT2
BAT1
AUX3/GPIO3
AUX2/GPIO2
AUX1/GPIO1
VCC
NC
X−
Y−
X+
Y+
AGND
15
DGND
16, 32
17
18
NC
PENIRQ
CS
19
DIN
20
STOPACQ
21
22
GPIO4
ALERT
23
DAV
24–25
26
27
NC
DCLK
DOUT
28
VDRIVE
Description
No Connect.
Battery Monitor Input. ADC Input Channel 7.
Battery Monitor Input. ADC Input Channel 6.
Auxiliary Analog Input. ADC Input Channel 5. Can be reconfigured as GPIO pin.
Auxiliary Analog Input. ADC Input Channel 4. Can be reconfigured as GPIO pin.
Auxiliary Analog Input. ADC Input Channel 3. Can be reconfigured as GPIO pin.
Power Supply Input. The VCC range for the AD7877 is from 2.2 V to 5.25 V.
No Connect.
Touch Screen Position Input.
Touch Screen Position Input. ADC Input Channel 2.
Touch Screen Position Input. ADC Input Channel 0.
Touch Screen Position Input. ADC Input Channel 1.
Analog Ground. Ground reference point for all analog circuitry on the AD7877. All analog input signals and any
external reference signal should be referred to this voltage.
Digital Ground. Ground reference for all digital circuitry on the AD7877. All digital input signals should be
referred to this voltage.
No Connect.
Pen Interrupt. Digital active low output (has 50 kΩ internal pull-up resistor).
Chip Select Input. Active low logic input. This input provides the dual function of initiating conversions on the
AD7877 and enabling the serial input/output register.
SPI® Serial Data Input. Data to be written to the AD7877’s registers should be provided on this input and is
clocked into the register on the rising edge of DCLK.
Stop Acquisition Pin. A signal applied to this pin can be monitored by the AD7877, so that acquisition of new
data by the ADC is halted while the signal is active. Used to reduce the effect of noise from an LCD screen on
the touch screen measurements.
Dedicated general-purpose logic input/output pin.
Digital Active Low Output. Interrupt output, which goes low if a GPIO data bit is set, or if the AUX1, TEMP1,
BAT1, or BAT2 measurements are out of range.
Data Available Output. Active low logic output. Asserts low when new data is available in the AD7877 results
registers. This output is high impedance when CS is high.
No Connect.
External Clock Input. Logic input. DCLK provides the serial clock for accessing data from the part.
Serial Data Output. Logic output. The conversion result from the AD7877 is provided on this output as a serial
data stream. The bits are clocked out on the falling edge of the DCLK input. This output is high impedance
when CS is high.
Logic Power Supply Input. The voltage supplied at this pin determines the operating voltage for the serial
interface of the AD7877.
Rev. A | Page 7 of 44
AD7877
Pin No.
29
30
31
Mnemonic
ARNG
AOUT
VREF
Description
When the DAC is in current output mode, a resistor from ARNG to GND sets the output range.
Analog Output Voltage or Current from DAC.
Reference output for the AD7877. The internal 2.5 V reference is available on this pin for use external to the
device. The reference output must be buffered before it is applied elsewhere in a system. A capacitor of 100nF
is strongly recommended between the VREF pin and GND to reduce system noise effects.
Alternatively, an external reference can be applied to this input. The voltage range for the external reference is
1.0 V to VCC. For the specified performance, it is 2.5 V on the AD7877.
Rev. A | Page 8 of 44
AD7877
TERMINOLOGY
Integral Nonlinearity
The maximum deviation from a straight line passing through
the endpoints of the ADC transfer function. The endpoints of
the transfer function are zero scale (a point 1 LSB below the
first code transition), and full scale (a point 1 LSB above the last
code transition).
Differential Nonlinearity
The difference between the measured and the ideal 1 LSB
change between any two adjacent codes in the ADC.
Offset Error
The deviation of the first code transition (00…000) to
(00…001) from the ideal (AGND + 1 LSB).
Gain Error
The deviation of the last code transition (111…110) to
(111…111) from the ideal (VREF − 1 LSB) after the offset error
has been adjusted out.
On Resistance
A measure of the ohmic resistance between the drain and the
source of the switch drivers.
Rev. A | Page 9 of 44
AD7877
TYPICAL PERFORMANCE CHARACTERISTICS
TA = 25°C, VCC = 2.7 V, VREF = 2.5 V, fSAMPLE = 125 kHz, fDCLK = 16 × fSAMPLE = 2 MHz, unless otherwise noted.
800
200
ADC, REF, AND DAC
180
160
CURRENT (nA)
CURRENT (µA)
700
ADC AND REF
600
140
120
–30
–10
0
30
TEMPERATURE (°C)
50
70
80
–50
90
03796-032
500
–50
03796-030
100
–30
–10
10
30
TEMPERATURE (°C)
50
70
90
Figure 8. Full Power-Down IDD vs. Temperature
Figure 5. Supply Current vs. Temperature
1000
0.6
0.5
0.4
900
DELTA FROM 25°C (LSB)
ADC, REF, AND DAC
700
ADC AND REF
600
0.2
0.1
0
–0.1
–0.2
–0.3
–0.4
03796-031
500
400
2.0
0.3
2.3
2.6
2.9
3.2
3.5 3.8
VCC (V)
4.1
4.4
4.7
–0.5
–0.6
–50
5.0
Figure 6. Supply Current vs. VCC
–30
–10
10
30
TEMPERATURE (°C)
50
70
90
Figure 9. Change in ADC Offset vs. Temperature
0.6
1.0
0.5
0.8
0.4
0.6
0.3
0.4
0.2
INL (LSB)
0.1
0
–0.1
–0.2
0.2
0
–0.2
–0.4
–0.3
–0.5
–0.6
–50
–30
–10
10
30
TEMPERATURE (°C)
50
70
03796-044
–0.6
–0.4
03796-039
DELTA FROM 25°C (LSB)
03796-040
CURRENT (µA)
800
–0.8
–1.0
0
90
Figure 7. Change in ADC Gain vs. Temperature
500
1000
1500
2000 2500
CODE
Figure 10. ACD INL Plot
Rev. A | Page 10 of 44
3000
3500
4000
AD7877
1.0
16
0.8
14
REFERENCE CURRENT (µA)
0.6
0.2
0
–0.2
–0.4
–0.8
–1.0
0
500
1000
1500
2000 2500
CODE
3000
3500
10
8
6
4
2
03796-045
–0.6
12
0
–50
4000
Figure 11. ADC DNL Plot
03796-046
DNL (LSB)
0.4
–30
–10
10
30
TEMPERATURE (°C)
50
70
90
Figure 14. External Reference Current vs. Temperature
22
2.520
2.515
20
2.510
18
2.505
VREF (V)
RON (Ω)
X– TO GND
16
Y– TO GND
14
Y+ TO VDD
2.500
2.495
2.490
12
03796-048
X+ TO VDD
8
2.7
3.1
3.5
3.9
4.3
VDD (V)
4.7
5.1
03796-033
2.485
10
2.480
2.475
–50
5.5
Figure 12. Switch On Resistance vs. VCC
(X+, Y+: VCC to Pin; X−, Y−: Pin to GND)
–30
–10
10
30
TEMPERATURE (°C)
50
70
90
Figure 15. Internal VREF vs. Temperature
22
2.508
20
2.506
X– TO GND
18
VREF (V)
Y– TO GND
14
Y+ TO VDD
2.502
2.500
12
X+ TO VDD
8
–40
–20
0
20
40
TEMPERATURE (°C)
60
80
Figure 13. Switch On Resistance vs. Temperature
(X+, Y+: VCC to Pin; X−, Y−: Pin to GND)
2.496
2.6
03796-034
2.498
10
03796-049
RON (Ω)
2.504
16
2.9
3.2
3.5
3.8
4.1
VCC (V)
4.4
Figure 16. Internal VREF vs. VCC
Rev. A | Page 11 of 44
4.7
5.0
AD7877
6
3145
3135
3115
INTERNAL VREF (V)
ADC CODE (Decimal)
3125
3105
3095
3085
3075
NO CAP
0.711µs SETTLING TIME
3
100nF CAP
54.64µs SETTLING TIME
3055
3045
–50
–30
–10
10
30
TEMPERATURE (°C)
50
70
0
–20
90
1182
–10
INPUT TONE AMPLITUDE (dB)
10
1180
1179
1178
3.1
3.2
VCC (V)
3.3
60
80
100
120
3.4
3.5
SNR 70.25dB
THD 78.11dB
–30
–50
–70
–90
–110
–130
03796-042
1177
3.0
40
03796-035
TEMP1 CODE
1181
2.9
20
Figure 20. Internal VREF vs. Turn-On Time
1183
2.8
0
TURN-ON TIME (µs)
Figure 17. ADC Code vs. Temperature (2.7 V Supply)
1176
2.7
03796-047
03796-041
3065
–150
3.6
0
Figure 18. Temp1 vs. VCC
10k
20k
FREQUENCY
30k
40k
Figure 21. Typical FFT Plot for the Auxiliary Channels of the AD7877
at 90 kHz Sample Rate and 10 kHz Input Frequency
982
3.50
3.25
981
DAC O/P SOURCE ABILITY
3.00
2.75
DAC O/P LEVEL (V)
2.50
979
978
977
2.25
2.00
1.75
1.50
1.25
1.00
975
2.7
2.8
2.9
3.0
3.1
3.2
VCC (V)
3.3
3.4
3.5
3.6
0.50
DAC O/P SINK ABILITY
0.25
0
0
Figure 19. Temp0 vs. VCC
03796-036
0.75
976
03796-043
TEMP0 CODE
980
1
2
3
4
5
6
7
SOURCE/SINK CURRENT (mA)
8
Figure 22. DAC Source and Sink Current Capability
Rev. A | Page 12 of 44
9
10
AD7877
∆: 144mV
@: 1.296V
1
CH1 200mV CH2 100mV
M2.00µs
CH1
03796-050
03796-037
VDD = 3V
TEMPERATURE = 25°C
780mV
–2
Figure 23. DAC O/P Settling Time (Zero Scale to Half-Scale)
400
DAC SINK CURRENT
300
200
100
03796-038
DAC SINK CURRENT (µA)
500
0
25
50
75
100 125 150 175
INPUT CODE (Decimal)
200
225
0
ERROR (%)
1
Figure 25. Typical Accuracy for Battery Channel (25°C)
600
0
–1
250
Figure 24. DAC Sink Current vs. Input Code
Rev. A | Page 13 of 44
2
AD7877
CIRCUIT INFORMATION
The core of the AD7877 is a high speed, low power, 12-bit
analog-to-digital converter (ADC) with input multiplexer,
on-chip track-and-hold, and on-chip clock. The results of
conversions are stored in 11 results registers, and the results
from one auxiliary input and two battery inputs can be
compared with high and low limits stored in limit registers to
generate an out-of-limit ALERT. The AD7877 also contains low
resistance analog switches to switch the X and Y excitation
voltages to the touch screen, a STOPACQ pin to control the
ADC acquisition period, 2.5 V reference, on-chip temperature
sensor, and 8-bit DAC to control LCD contrast. The high speed
SPI serial bus provides control of, and communication with, the
device.
Operating from a single supply from 2.2 V to 5 V, the AD7877
offers throughput rates of up to 125 kHz. The device is available
in a 5 mm by 5 mm 32-lead lead frame chip scale package.
The data acquisition system of the AD7877 has a number of
advanced features:
•
Input channel sequenced automatically or selected by
the host
•
STOPACQ feature to reduce noise from LCD
•
Averaging of from 1 to 16 conversions for noise
reduction
•
Programmable acquisition time
•
Power management
•
Programmable ADC power-up delay before first
conversion
•
Choice of internal or external reference
•
Conversion at preprogrammed intervals
CONDUCTIVE ELECTRODE
ON BOTTOM SIDE
PLASTIC FILM WITH
TRANSPARENT, RESISTIVE
COATING ON BOTTOM SIDE
Y+
X–
Y–
X+
CONDUCTIVE ELECTRODE
ON TOP SIDE
PLASTIC FILM WITH
TRANSPARENT, RESISTIVE
COATING ON TOP SIDE
LCD SCREEN
03796-005
The AD7877 is a complete, 12-bit data acquisition system for
digitizing positional inputs from a touch screen in PDAs and
other devices. In addition, it can monitor two battery voltages,
ambient temperature, and three auxiliary analog voltages, with
high and low limit comparisons on three of the inputs, and has
up to four general-purpose logic I/O pins.
Figure 26. Basic Construction of a Touch Screen
The Y layer has conductive electrodes running along the top
and bottom edges, allowing the application of an excitation
voltage down the layer from top to bottom.
Provided that the layers are of uniform resistivity, the voltage at
any point between the two electrodes is proportional to the
horizontal position for the X layer and the vertical position for
the Y layer.
When the screen is touched, the two layers make contact. If only
the X layer is excited, the voltage at the point of contact, and
therefore the horizontal position, can be sensed at one of the
Y layer electrodes. Similarly, if only the Y layer is excited, the
voltage, and therefore the vertical position, can be sensed at one
of the X electrodes. By switching alternately between X and
Y excitation and measuring the voltages, the X and Y coordinates of the contact point can be found.
In addition to measuring the X and Y coordinates, it is also
possible to estimate the touch pressure by measuring the
contact resistance between the X and Y layers. The AD7877 is
designed to facilitate this measurement.
TOUCH SCREEN PRINCIPLES
A 4-wire touch screen consists of two flexible, transparent,
resistive-coated layers that are normally separated by a small air
gap. The X layer has conductive electrodes running down the
left and right edges, allowing the application of an excitation
voltage across the X layer from left to right.
Figure 28 shows an equivalent circuit of the analog input
structure of the AD7877, showing the touch screen switches, the
main analog multiplexer, the ADC with analog and differential
reference inputs, and the dual 3-to-1 multiplexer that selects the
reference source for the ADC.
Rev. A | Page 14 of 44
AD7877
VCC
The voltage seen at the input to the ADC in Figure 28 is
VIN = VCC ×
X+
X–
REF
INT/EXT
Y+
Y–
X– Y– GND X+ Y+ VREF
DUAL 3-1
MUX
9 TO 1
I/P
MUX
AUX1/GPIO2
AUX2/GPIO3
AUX3/GPIO4
REF–
IN+
BAT1
RY −
(1)
RYTOTAL
The advantage of the single-ended method is that the touch
screen excitation voltage can be switched off once the signal has
been acquired. Because a screen can draw over 1 mA, this is a
significant consideration for a battery-powered system.
REF+
12-BIT SUCCESSIVE
APPROXIMATION ADC
WITH TRACK-AND-HOLD
03796-006
BAT2
TEMPERATURE
SENSOR
Figure 27. Analog Input Structure
The AD7877 can be set up to convert specific input channels or
to convert a sequence of channels automatically. The results of
the ADC conversions are stored in the results registers. See the
Serial Interface section for details.
When measuring the ancillary analog inputs (AUX1 to AUX3,
BAT1 and BAT2), the ADC uses the internal reference, or an
external reference applied to the VREF pin, and the measurement
is referred to GND.
MEASURING TOUCH SCREEN INPUTS
When measuring the touch screen inputs, it is possible to
measure using the internal (or external) reference, or to use the
touch screen excitation voltage as the reference and perform a
ratiometric, differential measurement. The differential method
is the default and is selected by clearing the SER/DFR bit
(Bit 11) in Control Register 1. The single-ended method is
selected by setting this bit.
Single-Ended Method
The single-ended method is illustrated for the Y position in
Figure 28. For the X position, the excitation voltage would be
applied to X+ and X− and the voltage measured at Y+.
The disadvantages of the single-ended method are as follows:
• It can be used only if VCC is close to VREF. If VCC is greater than
VREF, some positions on the screen are outside the range of
the ADC. If VCC is less than VREF, the full range of the ADC is
not utilized.
• The ratio of VCC to VREF must be known. If VREF and/or VCC
vary relative to one another, this can introduce errors.
• Voltage drops across the switches can introduce errors. Touch
screens can have a total end-to-end resistance of from 200 Ω
to 900 Ω. Taking the lowest screen resistance of 200 Ω and a
typical switch resistance of 14 Ω, this could reduce the apparent excitation voltage to 200/228 × 100 = 87% of its actual
value. In addition, the voltage drop across the low-side switch
adds to the ADC input voltage. This introduces an offset into
the input voltage, which means that it can never reach zero.
The single-ended method is adequate for applications in which
the input device is a fairly blunt and imprecise instrument such
as a finger.
Ratiometric Method
The ratiometric method is illustrated in Figure 29. Here, the
negative input of the ADC reference is tied to Y− and the
positive input is connected to Y+, so the screen excitation
voltage provides the reference for the ADC. The input of the
ADC is connected to X+ to determine the Y position.
VCC
VCC
Y+
Y+
VREF
X+
INPUT
(VIA MUX)
REF–
Y–
REF–
Y–
03796-007
GND
GND
REF+
ADC
TOUCH
SCREEN
ADC
TOUCH
SCREEN
INPUT
(VIA MUX)
03796-008
X+
REF+
Figure 29. Ratiometric Conversion of Touch Screen Inputs
Figure 28. Single-Ended Conversion of Touch Screen Inputs
Rev. A | Page 15 of 44
AD7877
MEASURE
X POSITION
For greater accuracy, the ratiometric method has two significant
advantages:
X+
TOUCH
RESISTANCE
• The reference to the ADC is provided from the actual voltage
across the screen, so voltage drops across the switches have
no effect.
X–
Y–
Y+
X+
MEASURE
Z1 POSITION
• Because the measurement is ratiometric, it does not matter if
the voltage across the screen varies in the long term. However,
it must not change after the signal has been acquired.
TOUCH
RESISTANCE
The disadvantage of the ratiometric method is that the screen
must be powered up all the time, because it provides the
reference voltage for the ADC.
Y–
X–
Y+
X+
TOUCH
RESISTANCE
The pressure applied to the touch screen via a pen or finger can
also be measured with the AD7877 using some simple calculations. The contact resistance between the X and Y plates is
measured. This provides a good indication of the size of the
depressed area and, therefore, the applied pressure. The area of
the spot touched is proportional to the size of the object
touching it. The size of this resistance (RTOUCH) can be calculated
using two different methods.
First Method
The first method requires the user to know the total resistance
of the X-plate tablet (RX). Three touch screen conversions are
required:
Y–
X–
MEASURE
Z2 POSITION
03796-009
TOUCH-PRESSURE MEASUREMENT
Figure 30. Three Measurements Required for Touch Pressure
Second Method
The second method requires that the resistance of the X-plate
and Y-plate tablets be known. Three touch screen conversions
again are required, a measurement of the X Position (XPOSITION),
Y Position (YPOSITION), and Z1 position.
The following equation also calculates the touch resistance:
• Measurement of the X position, XPOSITION (Y+ input).
RTOUCH = RXPlate × (XPOSITION /4096) × [(4096/Z1) − 1]
(3)
− RYPlate × [1 − (YPOSITION /4096)]
• Measurement of the Y− input with the excitation voltage
applied to Y+ and X− (Z1 measurement).
STOPACQ PIN
• Measurement of the X+ input with the excitation voltage
applied to Y+ and X− (Z2 measurement).
These three measurements are illustrated in Figure 30.
The AD7877 has two special ADC channel settings that
configure the X and Y switches for Z1 and Z2 measurement and
store the results in the Z1 and Z2 results registers. The Z1
measurement is ADC Channel 1010b, and the result is stored in
the register with Read Address 11010b. The Z2 measurement is
ADC Channel 0010b, and the result is stored in the register with
Read Address 10010b.
As explained previously, touch screens are composed of two
resistive layers, normally placed over an LCD screen. Because
these layers are in close proximity to the LCD screen, noise can
be coupled from the screen onto these resistive layers, causing
errors in the touch screen positional measurements.
For example, a jitter might be noticeable in the cursor onscreen. In most LCD touch screen systems, a signal, such as an
LCD invert signal or other control signal, is present, and noise is
usually coupled onto the touch screen during this signal’s active
period, as shown in Figure 31.
The touch resistance can then be calculated using the following
equation:
LCD SIGNAL
(2)
TOUCH SCREEN
SIGNAL
NOISY
PERIOD
NOISY
PERIOD
Figure 31. LCD Noise Affects Touch Screen Measurements
Rev. A | Page 16 of 44
03796-010
RTOUCH = (RXPlate) × (XPOSITION /4096 × [Z2/Z1) − 1]
Y+
AD7877
It is only during the sample or acquisition phase of the
AD7877’s ADC operation that noise from the LCD screen has
an effect on the ADC’s measurements. During the hold or
conversion phase, the noise has no effect, because the voltage at
the input of the ADC has already been acquired. Therefore, to
minimize the effect of noise on the touch screen measurements,
the ADC acquisition phase should be halted.
The LCD control signal should be applied to the STOPACQ pin.
To ensure that acquisition never takes place during the noisy
period when the LCD signal is active, the AD7877 monitors this
signal. No acquisitions take place when the control signal is
active. Any acquisition that is in progress when the signal
becomes active is aborted and restarts when the signal becomes
inactive again.
To accommodate signals of different polarities on the
STOPACQ pin, a user-programmable register bit is used to
indicate whether the signal is active high or low. The POL bit is
Bit 3 in Control Register 2, Address 02h. Setting POL to 1
indicates that the signal on STOPACQ is active high; setting
POL to 0 indicates that it is active low. POL defaults to 0 on
power-up. To disable monitoring of STOPACQ, the pin should
be tied low if POL = 1, or tied high if POL = 0. Under no
circumstances should the pin be left floating.
The signal on STOPACQ has no effect while the ADC is in
conversion mode, or during the first conversion delay time. (See
the Control Registers section for details on first conversion
delay.)
When enabled, the STOPACQ monitoring function is implemented on all input channels to the ADC: AUX1, AUX2, BAT1,
BAT2, TEMP1, and TEMP2, as well as on the touch screen input
channels.
TEMPERATURE MEASUREMENT
Two temperature measurement options are available on the
AD7877: the single conversion method and the differential
conversion method. The single conversion method requires
only a single measurement on ADC Channel 1000b. Differential
conversion requires two measurements, one on ADC Channel
1000b and a second on ADC Channel 1001b. The results are
stored in the results registers with Addresses 11000b (TEMP1)
and 11001b (TEMP2). The AD7877 does not provide an explicit
output of the temperature reading. Some external calculations
must be performed by the system. Both methods are based on
an on-chip diode measurement.
Single Conversion Method
The single conversion method makes use of the fact that the
temperature coefficient of a silicon diode is approximately
−2.1 mV/°C. However, this small change is superimposed on the
diode forward voltage, which can have a wide tolerance. It is,
therefore, necessary to calibrate by measuring the diode voltage
at a known temperature to provide a baseline from which the
change in forward voltage with temperature can be measured.
This method provides a resolution of approximately 0.3°C and a
predicted accuracy of ±2.5°C.
The temperature limit comparison is performed on the result in
the TEMP1 results register, which is simply the measurement of
the diode forward voltage. The values programmed into the
high and low limits should be referenced to the calibrated diode
forward voltage to make accurate limit comparisons. An
example is shown in the Limit Comparison section.
Differential Conversion Method
The differential conversion method is a 2-point measurement.
The first measurement is performed with a fixed bias current
into a diode (when the TEMP1 channel is selected), and the
second measurement is performed with a fixed multiple of the
bias current into the same diode (when the TEMP2 channel is
selected). The voltage difference in the diode readings is
proportional to absolute temperature and is given by the
following formula:
∆VBE = (KT/q) × (1n N)
(4)
where:
VBE represents the diode voltage.
N is the bias current multiple (typical value for AD7877 =120).
k is Boltzmann’s constant.
q is the electron charge.
This method provides a resolution of approximately 1.6°C, and
a guaranteed accuracy of ±4°C without calibration. Determination of the N value on a part-by-part basis improves accuracy.
Assuming a current multiple of 120, which is a typical value for
the AD7877, taking Boltzmann’s constant, k = 1.38054 ×
10−23 electrons V/°K, the electron charge q = 1.602189 × 10−19,
then T, the ambient temperature in Kelvin, would be calculated
as follows:
∆VBE = (KT/q) × (1n N)
T°K = (∆VBE × q)/(k × 1n N)
= ∆VBE × 1.602189 × 10−19)/(1.38054 × 10−23 × 4.65)
T°C = 2.49 × 103 × ∆VBE − 273
∆VBE is calculated from the difference in readings from the first
conversion and second conversion. The user must perform the
calculations to get ∆VBE, and then calculate the temperature
value in degrees.
Figure 32 shows a block diagram of the temperature
measurement circuit.
Rev. A | Page 17 of 44
AD7877
TEMP1
TEMP2
Example:
105 × I
MUX
The internal 2.5 V reference is used.
ADC
VBE
1.
LSB size = 2.5 V/4096 = 6.1 × 10−4 V (610 µV).
2.
TEMP1 = 880 and TEMP2 = 1103:
∆VBE = (1103 − 880) × 6.1× 10−4 = 0.136 V
3.
T = 0.136 × 2490 − 273 = 65°C.
03796-011
I
Figure 32. Block Diagram of Temperature Measurement Circuit
BATTERY MEASUREMENT
Temperature Calculations
If an explicit temperature reading in °C is required, then this
can be calculated as follows for the single measurement
method:
1.
Calculate the scale factor of the ADC in degrees per LSB:
Degrees per LSB = ADC LSB size/−2.1 mV =
VREF/4096)/−2.1 mV
2.
Save the ADC output DCAL at the calibration temperature
TCAL.
3.
Take ADC reading DAMB at temperature to be measured
TAMB.
4.
Calculate the difference in degrees between TCAL and TAMB
using
The AD7877 can monitor battery voltages from 0.5 V to 5 V on
two inputs, BAT1 and BAT2. Figure 33 shows a block diagram
of a battery voltage monitored through the BAT1 pin. The
voltage to the VCC pin of the AD7877 is maintained at the
desired supply voltage via the dc/dc regulator while the input to
the regulator is monitored. This voltage on BAT1 is divided
down by 2 internally, so that a 5 V battery voltage is presented to
the ADC as 2.5 V. To conserve power, the divider circuit is on
only during the sampling of a voltage on BAT1. The BAT2 input
circuitry is identical.
The BAT1 input is ADC Channel 0110b and the result is stored
in Register 10110b. The BAT2 input is ADC Channel 0111b and
the result is stored in Register 10111b.
DC-DC
CONVERTER
BATTERY
0.5V TO 5V
VCC
BAT1
∆T = (DAMB − DCAL) × degrees per LSB
5.
5kΩ
VREF
SW
0.25V–2.5V
ADC
Add ∆T to TCAL.
5kΩ
03796-012
Example:
The internal 2.5 V reference is used.
1.
Degrees per LSB = (2.5/4096)/−2.1 × 10−3 = −0.291.
2.
The ADC output is 983 decimal at 25°C, equivalent to a
diode forward voltage of 0.6 V.
3.
The ADC output at TAMB is 880.
4.
∆T = (880 − 983) × −0.291 = 30°.
5.
TAMB = 25 + 30 = 55°C.
Figure 33. Block Diagram of Battery Measurement Circuit
Figure 33 shows the ADC using the internal reference of 2.5 V.
If a different reference voltage is used, then the maximum
battery voltage that the AD7877 can measure changes. The
maximum voltage measurable is VREF × 2, because this voltage
gives a full-scale output from the ADC. If a smaller reference is
used, such as 2 V, then the maximum battery voltage measurable
is 4 V. If a larger reference is used, such as 3.5 V, then the
maximum battery voltage measurable is 7 V. The internal
reference is particularly suited for use when measuring Li-Ion
batteries, where the minimum voltage is about 2.7 V and the
maximum is about 4.2 V. A proper choice of external reference
ensures that other voltage ranges can be accommodated.
To calculate the temperature explicitly using the differential
method:
1.
Calculate the LSB size of the ADC in V:
LSB = VREF/4096
2.
Subtract TEMP1 from TEMP2 and multiply by LSB size to
get ∆VBE.
3.
Multiply by 2490 and subtract 273 to get the temperature
in °C.
Rev. A | Page 18 of 44
AD7877
AUXILIARY INPUTS
The AD7877 has three auxiliary analog inputs, AUX1 to AUX3.
These channels have a full-scale input range from 0 V to VREF.
The ADC channel addresses for AUX1 to AUX3 are 0011b,
0100b, and 0101b, and the results are stored in Registers 10011b,
10100b, and 10101b. These pins can also be reconfigured as
general-purpose logic inputs/outputs, as described in the GPIO
Configuration section.
LIMIT COMPARISON
The AUX1 measurement, the two battery measurements, and
the TEMP1 measurement can all be compared with high and
low limits, and an out-of-limit result made to generate an alarm
output at the ALERT pin. The limits are stored in registers with
addresses from 00100b to 01011b. After a measurement from
any one of the four channels is converted, it is compared with
the corresponding high and low limits. An out-of-limit result
sets one of the status bits in the alert status/enable register. For
details on these and other registers, see the Register Maps and
Detailed Register Descriptions sections. For details on writing
and reading data, see the Serial Interface section.
As mentioned previously, the temperature comparison is made
using the result of the TEMP1 measurement, which is the diode
forward voltage. Because the temperature coefficient of the
diode is known but the actual forward voltage can have a wide
tolerance, it is not possible to program the high and low limit
registers with predetermined values.
Instead, it is necessary to calibrate the temperature measurement, calculate the TEMP1 readings at the high and low limit
temperatures, and then program those values into the limit
registers, as follows:
1.
Calculate LSB per degree = −2.1 mV/(VREF/4096).
2.
Save the calibration reading DCAL at calibration temperature
TCAL.
3.
Subtract TCAL from limit temperatures THIGH and TLOW to get
the difference in degrees between the limit temperatures
and the calibration temperature.
4.
Multiply this value by LSB per degree to get the value in
LSBs.
5.
Add these values to the digital value at the calibration
temperature to get the digital high and low limit values.
Example:
The internal 2.5 V reference is used.
1.
THIGH = +65°C and TLOW = −10°C.
2.
LSB per degree = −2.1 × 10−3/(2.5/4096) = −3.44.
3.
DCAL = 983 decimal at 25°C.
4.
DHIGH = (65 − 25) × −3.44 + 983 = 845.
5.
DLOW = (−10 − 25) × −3.44 + 983 = 1103.
Rev. A | Page 19 of 44
AD7877
CONTROL REGISTERS
Control Register 1 contains the ADC channel address, the
SER/DFR bit (to choose single or differential methods of touch
screen measurement), the register read address, and the ADC
mode bits. Control Register 1 should always be the last register
to be programmed prior to starting conversions. Its power-on
default value is 00h. To change any parameter after conversion
has begun, the part should first be put into mode 00, the
changes made, and then Control Register 1 reprogrammed,
ensuring that it is always the last register to be programmed
before conversions begin.
SER/
DFR
0
CHNL CHNL CHNL CHNL
ADD ADD ADD
ADD
3
2
1
0
RD
ADD
4
RD
ADD
3
RD
ADD
2
RD
ADD
1
RD
ADD
0
ADC
ADC
MODE MODE
1
0
03796-013
11
The AD7877 can also be programmed to convert a sequence of
selected channels automatically. The two modes for this type of
conversion are slave mode and master mode.
Figure 34. Control Register 1
Control Register 2 sets the timer, reference, polarity, first
conversion delay, averaging, and acquisition time. Its power-on
default value is 00h. See the Detailed Register Descriptions
section for more information on the control registers.
AVG
1
0
AVG
0
ACQ
1
ACQ
0
PM
1
PM
0
FCD
1
FCD
0
POL
REF
TMR
1
TMR
0
Figure 35. Control Register 2
CONTROL REGISTER 1
ADC Mode (Control Register 1 Bits <1:0>)
These bits select the operating mode of the ADC. The AD7877
has three operating modes. These are selected by writing to the
mode bits in Control Register 1. If the mode bits are 00, no
conversion is performed.
Table 5. Control Register 1 Mode Selection
Mode 1
0
0
Mode 0
0
1
1
1
0
1
Function
Do not convert (default)
Single-channel conversion, AD7877 in
slave mode
Sequence 0, AD7877 in slave mode
Sequence 1, AD7877 in master mode
If the mode bits are 01, a single conversion is performed on the
channel selected by writing to the channel bits of Control
Register 1 (Bits 7 to 10). At the end of the conversion, if the
TMR bits in Control Register 2 are set to 00, the mode bits
revert to 00 and the ADC returns to no convert mode until a
new conversion is initiated by the host. Setting the TMR bits to
a value other than 00 causes the conversion to be repeated, as
described in the Timer (Control Register 2 Bits <1:0>) section.
The flowchart in Figure 37 shows how the AD7877 operates in
mode 01.
03796-014
11
For slave mode operation, the channels to be digitized are
selected by setting the corresponding bits in Sequencer
Register 0. Conversion is initiated by writing 10b to the mode
bits of Control Register 1. The ADC then digitizes the selected
channels and stores the results in the corresponding results
registers. At the end of the conversion, if the TMR bits in
Control Register 2 are set to 00, the mode bits revert to 00 and
the ADC returns to no convert mode until a new conversion is
initiated by the host. Setting the TMR bits to a code other than
00 causes the conversion sequence to be repeated. The flowchart
in Figure 38 shows how the AD7877 operates in mode 10.
For master mode operation, the channels to be digitized are
written to Sequencer Register 1. Master mode is then selected
by writing 11 to the mode bits in Control Register 1. In this
mode, the wake-up on touch feature is active, so conversion
does not begin immediately. The AD7877 waits until the screen
is touched before beginning the sequence of conversions. The
ADC then digitizes the selected channels, and the results are
written to the results registers. The AD7877 waits for the screen
to be touched again, or for a timer event if the screen remains
touched, before beginning another sequence of conversions.
Figure 39 is a flowchart, showing how the AD7877 operates in
mode 11.
ADC Channel (Control Register 1 Bits <10:7>)
The ADC channel is selected by Bits 10:7 of Control Register 1
(CHADD3 to CHADD0). In addition, the SER/DFR bit, Bit 11,
selects between single-ended and differential conversion. A
complete list of channel addresses is given in Table 6.
For mode 0 (single-channel) conversion, the channel is selected
by writing the appropriate CHADD3 to CHADD0 code to
Control Register 1.
For sequential channel conversion, channels to be converted are
selected by setting bits corresponding to the channel number in
Sequencer Register 1 for slave mode sequencing or Sequencer
Register 2 for master mode sequencing.
For both single-channel and sequential conversion, normal
(single-ended) conversion is selected by clearing the SER/DFR
bit in Control Register 1. Ratiometric (differential) conversion is
selected by setting the SER/DFR bit.
Rev. A | Page 20 of 44
AD7877
Table 6. Codes for Selecting Input Channel and Normal or Ratiometric Conversion
Channel
0
1
2
3
4
5
6
7
8
9
10
0
1
2
3
4
5
6
7
8
9
10
-
SER/DFR
CHADD(3:0)
0000
0001
0010
0 01 1
0 1 00
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
10 1 1
1100
1101
1110
1111
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Analog Input
X+ (Y Position)
Y+ (X Position)
Y− (Z2)
AUX1
AUX2
AUX3
BAT1
BAT2
TEMP1
TEMP2
X+ (Z1)
X+ (Y Position)
Y+ (X Position)
Y− (Z2)
AUX1
AUX2
AUX3
BAT1
BAT2
TEMP1
TEMP2
X+ (Z1)
X Switches
Y Switches
OFF
ON
ON
OFF
X+ OFF, X− ON
Y+ ON, Y− OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
X+ OFF, X− ON
Y+ ON, Y− OFF
INVALID ADDRESS
INVALID ADDRESS
INVALID ADDRESS
INVALID ADDRESS
INVALID ADDRESS
OFF
ON
ON
OFF
X+ OFF, X− ON
Y+ ON, Y− OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
X+ OFF, X− ON
Y+ ON, Y− OFF
INVALID ADDRESS
INVALID ADDRESS
INVALID ADDRESS
INVALID ADDRESS
INVALID ADDRESS
+REF
Y+
X+
Y+
VREF
VREF
VREF
VREF
VREF
VREF
VREF
Y+
−REF
Y−
X−
X−
GND
GND
GND
GND
GND
GND
GND
X−
VREF
VREF
VREF
VREF
VREF
VREF
VREF
VREF
VREF
VREF
VREF
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
CONTROL REGISTER 2
Int/Ext Reference (Control Register 2 Bit <2>)
Timer (Control Register 2 Bits <1:0>)
If the REF bit in Control Register 2 is 0 (default value), the
internal reference is selected. If any connection is made to VREF
while the internal reference is selected (for example, to supply a
reference to other circuits), it should be buffered. An external
power supply should not be connected to this pin while REF is
equal to 0, because it might overdrive the internal reference.
Note also that, because the internal reference is 2.5 V, it operates
only with supply voltages down to 2.7 V. Below this value an
external reference should be used.
The TMR bits in Control Register 2 enable the ADC to
repeatedly perform a conversion or conversion sequence either
once only or at intervals of 512 µs, 1.024 ms, or 8.19 ms. In slave
mode, the timer starts as soon as the conversion sequence is
finished. In master mode, the timer starts at the end of a conversion sequence only if the screen remains touched. If the touch is
released at any stage, then the timer stops and, the next time the
screen is touched, a conversion sequence begins immediately.
Table 7. Control Register 2 Timer Selection
TMR1
0
0
1
1
TMR0
0
1
0
1
Function
Convert only once (default)
Every 1024 clocks (512 µs)
Every 2048 clocks (1.024 ms)
Every 16,384 clocks (8.19 ms)
If the REF bit is 1, the VREF pin becomes an input and the
internal reference is powered down. This overrides any setting
of the PM bits with regard to the reference. An external
reference can then be applied to the REF pin.
Rev. A | Page 21 of 44
AD7877
STOPACQ Polarity (Control Register 2 Bit <3>)
Acquisition Time (Control Register 2 Bits <9:8>)
This bit should be set according to the polarity of the signal
applied to the STOPACQ pin. If that signal is active high, that is,
no acquisitions should occur during the signal’s high period,
then the POL bit should be set to 1. If the signal is active low,
then the POL bit should be 0. The default value for POL is 0.
The ACQ bits in Control Register 2 allow the selection of
acquisition times for the ADC of 2 µs (default), 4 µs, 8 µs, or
16 µs. The user can program the ADC with an acquisition time
suitable for the type of signal being sampled. For example,
signals with large RC time constants might require longer
acquisition times.
First Conversion Delay (Control Register 2 Bits <5:4> )
The first conversion delay (FCD) bits in Control Register 2
program a delay of 500 ns (default), 128 µs, 1.024 ms, or 8.19 ms
before the first conversion, to allow the ADC time to power up.
This delay also occurs before conversion of the X and Y
coordinate channels, to allow extra time for screen settling, and
after the last conversion in a sequence, to precharge PENIRQ. If
the signal on the STOPACQ pin is being monitored and goes
active during the FCD, it is ignored until after the FCD period.
Table 10. Acquisition Time Selection
Table 8. First Conversion Delay Selection
Signals from touch screens can be extremely noisy. The AVG
bits in Control Register 2 allow multiple conversions to be
performed on each input channel and averaged to reduce noise.
A single conversion can be selected (no averaging), which is the
default, or 4, 8, or 16 conversions can be averaged. Only the final
averaged result is written into the results register.
FCD1
0
0
1
1
FCD
0
1
0
1
Function
1 clock delay (500 ns)
256 clocks delay (128 µs)
2048 clocks delay (1.024 ms)
16,384 clocks delay (8.19 ms)
ACQ1
0
0
1
1
ACQ0
0
1
0
1
Function
4 clock periods (2 µs)
8 clock periods (4 µs)
16 clock periods (8 µs)
32 clock periods (16 µs)
Averaging (Control Register 2 Bits <11:10>)
Table 11. Averaging Selection
The power management (PM) bits in Control Register 2 allow
the power management features of the ADC to be programmed.
If the PM bits are 00, the ADC is powered down permanently.
This overrides any setting of the mode bits in Control
Register 1. If the PM bits are 01, the ADC and the reference
both power down when the ADC is not converting. If the PM
bits are 10, the ADC and reference are powered up continuously.
If the PM bits are 11, the ADC, but not the reference, powers
down when the ADC is not converting.
Table 9. Power Management Selection
PM1
0
0
PM0
0
1
1
1
0
1
Function
Power down continuously (default)
Power down ADC and reference when
ADC is not converting (powers up with
FCD at start of conversion)
Powered up continuously
Power down ADC when ADC is not
converting (powers up with FCD at start
of conversion)
AVG1
0
0
1
1
AVG0
0
1
0
1
Function
ADC performs 1 average per channel
ADC performs 4 averages per channel
ADC performs 8 averages per channel
ADC performs 16 averages per channel
SEQUENCER REGISTERS
There are two sequencer registers on the AD7877. Sequencer
Register 0 controls the measurements performed during a slave
mode sequence. Sequencer Register 1 controls the measurements performed during a master mode sequence.
To include a measurement in a slave mode or master mode
sequence, the relevant bit must be set in Sequencer Register 0 or
Sequencer Register 1. Setting Bit 11 includes a measurement on
ADC Channel 0 in the sequence, which is the Y positional
measurement. Setting Bit 10 includes a measurement on ADC
Channel 1 (X+ measurement), and so on, through Bit 1 for
Channel 10. Figure 36 illustrates the correspondence between
the bits in the sequencer registers and the various measurements. Bit 0 in both sequencer registers is not used. See also the
Detailed Register Descriptions section.
11
0
Y+
X+
Z2
AUX
1
AUX
2
AUX
3
BAT
1
BAT
2
TEMP TEMP
1
2
Figure 36. Sequencer Register
Rev. A | Page 22 of 44
Z1
NOT
USED
03796-015
Power Management (Control Register 2 Bits <7:6>)
AD7877
HOST PROGRAMS
AD7877 IN MODE 10
HOST PROGRAMS
AD7877 IN MODE 01
IS FCD
REQUIRED?
VALID
SEQUENCE 0?
NO
NO
GOTO MODE 00
YES
YES
SELECT NEXT
CHANNEL
START FCD TIMER
IS FCD
FINISHED?
IS FCD
REQUIRED?
NO
NO
YES
YES
YES
START FCD TIMER
IS FCD
FINISHED?
IS STOPACQ
SIGNAL ACTIVE?
NO
YES
NO
IS STOPACQ
SIGNAL ACTIVE?
YES
START ACQUISITION TIMER
NO
START ACQUISITION TIMER
IS STOPACQ
SIGNAL ACTIVE?
YES
YES
NO
IS STOPACQ
SIGNAL ACTIVE?
NO
NO
IS ACQUISITION
TIME FINISHED?
IS ACQUISITION
TIME FINISHED?
NO
YES
CONVERT
SELECTED CHANNEL
YES
CONVERT
SELECTED CHANNEL
NO
IS AVERAGING
FINISHED?
IS AVERAGING
FINISHED?
YES
YES
WRITE RESULT TO
REGISTERS
WRITE RESULT TO
REGISTERS
LIMIT COMPARISON
LIMIT COMPARISON
NO
OUT-OF-LIMIT?
OUT-OF-LIMIT?
NO
YES
YES
UPDATE ALERT
ENABLE/STATUS
REGISTER
UPDATE ALERT
ENABLE/STATUS
REGISTER
ALERT
SOURCE
ENABLED?
NO
ALERT
SOURCE
ENABLED?
NO
NO
YES
ASSERT ALERT
OUTPUT*
YES
ASSERT ALERT
OUTPUT*
LAST CHANNEL
IN SEQUENCE?
NO
YES
ONCE-ONLY
MODE?
GOTO MODE 00
YES
YES
ONCE-ONLY
MODE?
GOTO MODE 00
NO
START TIMER
NO
START TIMER
YES
*NOTE: SEE EXPLANATION IN TEXT
NO
TIMER
FINISHED?
YES
*NOTE: SEE EXPLANATION IN TEXT
Figure 37. Single Channel Operation
03796-017
TIMER
FINISHED?
03796-016
NO
Figure 38. Slave Mode Sequencer Operation
Rev. A | Page 23 of 44
AD7877
INTERRUPTS
HOST PROGRAMS
AD7877 IN MODE 11
Data Available Output (DAV)
GOTO MODE 00
VALID
SEQUENCE 1?
NO
The data available output (DAV) indicates that new ADC data is
available in the results registers. While the ADC is idle or is
converting, DAV is high. Once the ADC has finished converting
and new data has been written to the results registers, DAV goes
low. Taking DAV low to read the registers resets DAV to a high
condition. DAV is also reset, if a new conversion is started by
the AD7877 because the timer expired. The host should attempt
to read the results registers only while DAV is low.
YES
IS
SCREEN
TOUCHED?
NO
YES
SELECT NEXT
CHANNEL
IS FCD
REQUIRED?
NO
YES
START FCD TIMER
CS
IS FCD
FINISHED?
NO
YES
tCONV
IS STOPACQ
SIGNAL ACTIVE?
AD7877
STATUS
NO
START ACQUISITION TIMER
YES
ADC
CONVERTING
NEW DATA HOST READS
AVAILABLE RESULTS
IDLE
Figure 40. Operation of DAV Output
IS STOPACQ
SIGNAL ACTIVE?
DAV is useful as a host interrupt in master mode. In this mode,
the host can program the AD7877 to automatically perform a
sequence of conversions, and can be interrupted by DAV at the
end of each conversion sequence.
NO
IS ACQUISITION
TIME FINISHED?
IDLE
SETUP
BY HOST
03796-019
DAV
YES
NO
YES
CONVERT
SELECTED CHANNEL
When the on-board timer is programmed to perform automatic
conversions, a limited time is available to the host to read the
results registers before another sequence of conversions begins.
The DAV signal is reset high when the timer expires, and the
host should not access the results registers while DAV is high.
NO
IS AVERAGING
FINISHED?
YES
WRITE RESULT TO
REGISTERS
LIMIT COMPARISON
OUT-OF-LIMIT?
Figure 41 shows the worst-case timings for reading the results
registers after DAV has gone low. The timer is set at a minimum,
and the conversion sequence includes all eleven possible ADC
channels. t1 is the time taken for acquisition and conversion on
one ADC channel. t2 shows the minimum timer delay, which is
1024 clock periods. t3 is the time taken to read all 11 result
registers. If the host wants to read all 11 registers, then it must
do so before the timer expires. t4 is the maximum time allowable
between DAV going low and the host beginning to read the
results registers. If t4 is exceeded, then all registers cannot be
read before the start of a new conversion, and incorrect data
could be read by the host.
NO
YES
UPDATE ALERT
ENABLE/STATUS
REGISTER
ALERT
SOURCE
ENABLED?
NO
YES
ASSERT ALERT
OUTPUT*
NO
LAST CHANNEL
IN SEQUENCE?
YES
YES
ONCE-ONLY
MODE?
NO
IS
SCREEN STILL
TOUCHED?
AD7877
STATUS
NO
t1
t2
CHANNEL 11
CONVERSION AND
ACQUISITION
TIMER INTERVAL
CHNL
1
YES
DAV
TIMER
FINISHED?
CS
YES
DOUT
NO
IS
SCREEN STILL
TOUCHED?
NO
*NOTE: SEE EXPLANATION IN TEXT
t3
03796-018
YES
t4
Figure 41. Timing for Reads after DAV Goes Low
Figure 39. Master Mode Sequencer Operation
Rev. A | Page 24 of 44
03796-020
START TIMER
AD7877
NOT
SCREEN TOUCHED
t2 = timer interval × tDCLK = (1024 × 50 ns) = 51.2 µs
NOT
TOUCHED
TOUCHED
PENIRQ
DETECTS
TOUCH
PENIRQ
PENIRQ
DETECTS
RELEASE
TWRITE = TREAD = 16 clk period × tDCLK = 800 ns
ADC
STATUS
t3 = maximum time taken to write read address and read
11 registers = 800 ns (write) + [800 ns (read) × 11] = 9.6 µs.
ADC IDLE
NOT
SCREEN TOUCHED
t4MAX = t2 − t3 = 51.2 µs − 9.6 µs = 41.6 µs
Pen Interrupt (PENIRQ)
Y+
VCC
VCC
50kΩ
PENIRQ
X+
ADC
STATUS
RELEASE NOT
DETECTED
PENIRQ
DETECTS
TOUCH
PENIRQ
The pen interrupt request output (PENIRQ) goes low whenever
the screen is touched. The pen interrupt equivalent output
circuitry is outlined in Figure 42. This is a digital logic output
with an internal pull-up resistor of 50 kΩ, which means it does
not need an external pull-up. The PENIRQ output idles high.
The PENIRQ circuitry is always enabled, except during
conversions.
TOUCHED
ADC IDLE
NOT
TOUCHED
PENIRQ
DETECTS
RELEASE
ADC
CONVERTING
ADC IDLE
03796-022
If fDCLK = 20 MHz (maximum), then tDCLK = 50 ns.
Figure 43. PENIRQ Operation for ADC Idle and ADC Converting
SYNCRONIZING THE AD7877 TO THE HOST CPU
The two suggested methods for synchronizing the AD7877 to
its host CPU are slave mode, in which the mode bits can be
either 01b or 10b, and master mode, in which the mode bits
are 11b.
X–
TOUCH
SCREEN
Y–
03796-021
PENIRQ
ENABLE
In slave mode, PENIRQ can be used as an interrupt to the host.
When PENIRQ goes low to indicate that the screen has been
touched, the host is awakened. The host can then program the
AD7877 to begin converting in either mode 01b or 10b, and can
read the result registers after the conversions have completed.
Figure 42. PENIRQ Output Equivalent Circuit
When the screen is touched, PENIRQ goes low. This can be
used to generate an interrupt request to the host. When the
screen touch ends, PENIRQ goes high immediately, if the ADC
is idle. If the ADC is converting, PENIRQ goes high when the
ADC becomes idle. The PENIRQ operation for these two
conditions is shown in Figure 43.
In master mode, DAV can also be used as an interrupt to the
host. However, the host should first initialize the AD7877 in
mode 11b. The host can then go into sleep mode to conserve
power. The wake-up on touch feature of the AD7877 is active in
this mode, so, when the screen is touched, the programmed
sequence of conversions begins automatically. When the DAV
signal asserts, the host reads the new data available in the
AD7877 results registers and returns to sleep mode. This
method can significantly reduce the load on the host.
Rev. A | Page 25 of 44
AD7877
8-BIT DAC
The AD7877 features an on-chip 8-bit DAC for LCD contrast
control. The DAC can be configured for voltage output by
clearing Bit 2 of the DAC register (Address 1110b), or for
current output by setting this bit.
The output voltage range can be set to 0 − VCC/2 by clearing
Bit 0 of the DAC register, or to 0 − VCC by setting this bit. In
current mode, the output range is selectable by an external
resistor, RRNG, connected between the ARNG pin and GND. This
sets the full-scale output current according to the following
equations:
In current mode, it is quite easy to calculate the resistor values
to give the required adjustment range in VOUT:
1.
Find the required maximum and minimum values of VOUT
from the LCD manufacturer’s data.
2.
Decide on the current around the feedback loop, which for
reasonable accuracy of the output voltage should be at least
100 times the input bias current of the dc–dc converter’s
comparator.
3.
Calculate R3 using the following equation:
IFS = VCC/(RRNG × 6)
R3 = VFB/IFB = VREF/IFB
so RRNG = VCC/(IFS × 6)
4.
In current mode, the DAC sinks current, that is, positive current
flows into ground. The maximum output current is 1000 µA.
The DAC is updated by writing to Address 1110b of the DAC
register. The 8 MSBs of the data-word are used for DAC data.
The most effective way to control LCD contrast with the DAC is
to use it to control the feedback loop of the dc-dc converter that
supplies the LCD bias voltage, as shown in Figure 44. The bias
voltage for graphic LCDs is typically in the range of 20 V to
25 V, and the dc–dc converter usually has a feedback loop that
attenuates the output voltage and compares it with an internal
reference voltage.
TO LCD
DC-DC
CONVERTER
AD7877
RRNG1
IOUT
VFB
5.
Because the voltage across R3 does not change, subtract
VREF from VOUTMAX and VOUTMIN to get the maximum and
minimum voltages across R2.
6.
Calculate the change in feedback current between
minimum and maximum output voltages:
∆I = VR2(MAX)/R2 − VR2(MIN)/R2
This is the required full-scale current of the DAC.
7.
Calculate RRNG from the equation given previously.
Example:
R12
R3
R2 = R3(VOUT(MIN) − VREF)/VREF
VOUT
COMP
VREF
1.
VCC = 5 V. VOUT(MIN) is 20 V and VOUT(MAX) is 25 V. VREF is
1.25 V.
2.
Allow 100 µA around the feedback loop.
3.
R3 = 1.25 V/100 µA = 12.5 kΩ. Use the nearest preferred
value of 12 kΩ and recalculate the feedback current as
GND
NOTES:
1R
RNG IS REQUIRED ONLY IF DAC IS IN CURRENT MODE.
2R1 IS REQUIRED ONLY IF DAC IS IN VOLTAGE MODE.
03796-023
ARNG
R2
AOUT
8-BIT
DAC
Calculate R2 for the minimum value of VOUT, when the
DAC has no effect:
Figure 44. Using the DAC to Adjust LCD Contrast
The circuit operates as follows. If the DAC is in current mode
when the DAC output is zero, it has no effect on the feedback
loop. Irrespective of what the DAC does, the feedback loop
maintains the voltage across R4, VFB, equal to VREF, and the
output voltage VOUT is
VREF × (R2 + R3)/R3
As the DAC output is increased, it increases the feedback
current, so the voltage across R2 and, therefore, the output
voltage also increase. Note that the voltage across R3 does not
change. This is important for calculation of the adjustment
range.
IFB = 1.25 V/12 kΩ = 104 µA
4.
R2 = (20 V − 1.25 V)/104 µA = 180 kΩ.
5.
∆I = 23.75 V/180 kΩ − 18.75 V/180 kΩ = 28 µA.
6.
RRNG = 5 V/(6 × 28 µA) = 30 kΩ.
In voltage mode, the circuit operation depends on whether the
maximum output voltage of the DAC exceeds the dc–dc
converter VREF.
When the DAC output voltage is zero, it sinks the maximum
current through R1. The feedback current, and, therefore, VOUT
are at their maximum. As the DAC output voltage increases, the
sink current and, therefore, the feedback current decrease, and
Rev. A | Page 26 of 44
AD7877
VOUT falls. If the DAC output exceeds VREF, it starts to source
current, and VOUT has to further decrease to compensate. When
the DAC output is at full scale, VOUT is at its minimum.
Note that the effect of the DAC on VOUT is opposite in voltage
mode to that in current mode. In current mode, increasing DAC
code increases the sink current, so VOUT increases with
increasing DAC code. In voltage mode, increasing DAC code
increases the DAC output voltage, reducing the sink current.
5.
R1 = VFS/∆.
6.
Calculate R3 from R1 and R using
R3 = (R1 × RP)/(R1 − RP)
Example:
1.
VCC = 5 V and VFS = VCC. VOUT(MIN) is 20 V and VOUT(MAX) is
25 V. VREF is 1.25 V. Allow 100 µA around the feedback
loop.
Calculate the resistor values as follows:
1.
Decide on the feedback current as before.
2.
RP = 1.25 V/100 µA = 12.5 kΩ.
2.
Calculate the parallel combination of R1 and R3 when the
DAC output is zero:
3.
R2 = 12.5 kΩ × (25 Ω − 1.25 Ω)/1.25 Ω = 237 kΩ.
RP = VREF/IFB
4.
∆I = 25 V/240 kΩ − 20 V/240 kΩ = 21 µA.
Calculate R2 as before, but use RP and VOUTMAX:
5.
R1 = 5 V/21 µA = 238 kΩ.
3.
Use nearest preferred value of 240 kΩ.
R2 = RP(VOUT(MAX) − VREF)/VREF
4.
Use nearest preferred value of 250 kΩ.
Calculate the change in feedback current between
minimum and maximum output voltages as before using
6.
R3 = (180 kΩ × 12.5 kΩ)/(180 kΩ − 12.5 kΩ) =13.4 kΩ.
Use nearest preferred value of 13 kΩ.
∆I = VR2(MAX)/R2 − VR2(MIN)/R2
This is equal to the change in current through R1 between
zero output and full scale, which is also given by
The actual adjustment range using these values is 21 V to 26 V.
∆I = current at zero − current at full scale
= V/R1 − (VREF − V)/R1
= V/R1
Rev. A | Page 27 of 44
AD7877
SERIAL INTERFACE
The AD7877 is controlled via a 3-wire serial peripheral interface
(SPI). The SPI has a data input pin (DIN) for inputting data to
the device, a data output pin (DOUT) for reading data back
from the device, and a data clock pin (DCLK) for clocking data
into and out of the device. A chip-select pin (CS) enables or
disables the serial interface.
Register Address 1111b is not a physical register, but enables an
extended writing mode that allows writing to the GPIO
configuration registers. When the register address is 1111b, the
next four bits of the data-word are the address of a GPIO
configuration register and the eight LSBs are the GPIO configuration data. For details on the configuration of the GPIO pins,
see the General-Purpose I/O Pins section.
WRITING DATA
Register Address 0001b is a physical register, Control Register 1,
but this is a special register. It contains data for setting up the
ADC channel and operating mode, but Bits 20 to 6 are the
register address for reading. These define which register is read
back during the next read operation. Control Register 1 should
be the last register in the AD7877 to be programmed before
starting a conversion. The three types of data-words used for
writing are shown in Figure 45.
Data is written to the AD7877 in 16-bit words. The first four
bits of the word are the register address, which tells the AD7877
which register to write to. The next 12 bits are data. How the
AD7877 handles the data bits depends on the register address.
Register Address 0000b is a dummy address, which does
nothing. Register addresses from 0010b to 1110b are 12-bit
registers that perform various functions as described in the
register map.
16-BIT DATA-WORD
D15
D14
D13
D12
D11
D10
D9
WADD3
WADD2
WADD1
WADD0
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
D6
D5
D4
D3
D2
D1
D0
D4
D3
D2
D1
D0
RADD0
MODE 1
MODE 0
WRITING TO A REGISTER
D8
D7
4-BIT REGISTER WRITE ADDRESS
12 BITS DATA
EXTENDED WRITE OPERATION TO GPIO REGISTERS
1
1
1
1
EADD3
EXTENDED WRITE ADDRESS
EADD2
EADD1
EADD0
D7
D6
D5
4-BIT EXTENDED ADDRESS
8 BITS GPIO DATA
WRITING TO CONTROL REGISTER 1 TO SET ADC CHANNEL, MODE, AND READ REGISTER ADDRESS
0
0
0
0
SER/DFR CHADD3 CHADD2 CHADD1 CHADD0
CONTROL REGISTER 1 ADDRESS
RADD4
ADC CHANNEL ADDRESS
RADD3
RADD2
RADD1
5-BIT READ REGISTER ADDRESS
OPERATING
MODE
03796-024
NORMAL (SINGLE-ENDED)/
RATIOMETRIC (DIFFERENTIAL)
CONVERSION
Figure 45. Designation of Data-Word Bits in AD7877 Write Operations
CS
1
16
1
16
DCLK
0000 + 12-BIT DATA3
DOUT1
HIGH-Z
0000 + 12-BIT DATA3
D15
D0
HIGH-Z
D15
REGISTER n DATA4
D0
REGISTER n + 1 DATA4
4-BIT ADDRESS + 12-BIT DATA
D15
D0
NOTES:
1DATA IS CLOCKED OUT ON THE FALLING EDGE OF DCLK.
2INPUT DATA IS SAMPLED ON THE RISING EDGE OF DCLK.
3FOR 8-BIT REGISTERS, 8 LEADING ZEROS PRECEDE 8 BITS OF DATA.
4REGISTER READ ADDRESS INCREMENTS AUTOMATICALLY, PROVIDED THAT A NEW ADDRESS IS NOT WRITTEN TO CONTROL REGISTER 1.
Figure 46. Overall Read/Write Timing
Rev. A | Page 28 of 44
03796-025
DIN2
AD7877
WRITE TIMING
No serial interface operations can take place while CS is high.
To write to the AD7877, CS must be taken low. To write to the
device, a burst of 16 clock pulses is input to DCLK while the
write data is input to DIN. Data is clocked in on the rising edge
of DCLK. If multiple write operations are to be performed, CS
must be taken high after the end of each write operation before
another write operation can be performed by taking CS low
again.
READING DATA
Data is available on the DOUT pin following the falling edge of
CS, when the device is being clocked. The MSB is clocked out
on the falling edge of CS, with subsequent data bits clocked out
on the falling edge of DCLK.
After CS is taken low and the device is clocked, the AD7877
outputs data from the register whose read address is currently
stored in Control Register 1. Once this data has been output, the
address increments automatically. CS must be taken high
between reads. When CS is taken low again, reading continues
from the register whose read address is in Control Register 1,
provided that a write operation does not change the address. If
the register read address reaches 11111b, it is then reset to zero.
This feature allows all registers to be read out in sequence
without having to explicitly write all their addresses to the
device.
Note that because data-words are 16 bits long, but the data
registers are only 12 bits long, or 8 bits in the case of GPIO
registers, the first four bits of a readback data-word are zeros, or
the first 8 bits in the case of a GPIO register.
VDRIVE PIN
The supply voltage to all pins associated with the serial interface
(DAV, DIN, DOUT, DCLK, CS, PENIRQ, and ALERT) is
separate from the main VCC supply and is connected to the
VDRIVE pin. This allows the AD7877 to be connected directly to
processors whose supply voltage is less than the minimum
operating voltage of the AD7877, in fact, as low as 1.7 V.
Rev. A | Page 29 of 44
AD7877
GENERAL-PURPOSE I/O PINS
The AD7877 has one dedicated general-purpose logic input/
output pin (GPIO4), and any or all of the three auxiliary analog
inputs can also be reconfigured as GPIOs. Associated with the
GPIOs are two 8-bit control registers and one 8-bit data register,
which are accessed using the extended write mode.
As mentioned previously, GPIO registers are written to using
the extended writing mode. The first four bits of the data-word
must be 1111b to access the extended writing map, and the next
four bits are the GPIO register address. This leaves 8 bits for the
GPIO register data, because all GPIO registers are 8 bits.
The GPIO control registers are located at Extended Writing
Map Addresses 0000b and 0001b, and the GPIO data register is
at Address 0010b. GPIO registers are read in the same way as
other registers, by writing a 5-bit address to Control Register 1.
The GPIO registers are located at Read Addresses 11011b to
11101b.
GPIO CONFIGURATION
Each GPIO pin is configured by four bits in one of the GPIO
control registers and has a data bit in the GPIO data register.
The GPIO configuration bits are described in the following
sections and in Table 12. Also see the Detailed Register
Descriptions section.
Enable—EN
These bits enable or disable the GPIO pins. When EN = 0, the
corresponding GPIO pin is configured as the alternate function
(AUX input). The other GPIO configuration bits have no effect,
if the particular GPIO is not enabled. When EN = 1, the pin is
configured as a GPIO pin. GPIO4, which does not have an
alternate function, does not have an EN bit; it is always enabled.
Direction—DIR
These bits set the direction of the GPIO pins. When DIR = 0,
the pin is an output. Setting or clearing the relevant bit in the
GPIO data register outputs a value on the corresponding GPIO
pin. The output value depends on the POL bit.
If POL = 1 and DIR = 0, a 1 in the GPIO data register bit puts a
1 on the corresponding GPIO output pin. A 0 in the GPIO data
register bit puts a 0 on the GPIO output pin.
If POL = 0 and DIR = 1, a 1 at the input pin sets the corresponding GPIO data bit to 0. A 0 at the input pin clears the
corresponding GPIO data bit to 1.
If POL = 0 and DIR = 0, a 1 in the GPIO data register bit puts a
0 on the corresponding GPIO output pin. A 0 in the GPIO data
register bit puts a 1 on the GPIO output pin.
Alert Enable—ALEN
GPIOs can operate as interrupt sources to trigger the ALERT
output. This is controlled by the alert enable (ALEN) bits in the
GPIO configuration registers. When ALEN = 1, the corresponding GPIO can trigger an ALERT. When ALEN = 0, the corresponding GPIO cannot cause the ALERT output to assert.
ALERT is asserted low, if any GPIO data register bit is set when
the GPIO is configured as an input. The GPIO data bit is set, if a
1 appears on the GPIO input pin when POL = 1, or if a 0
appears on the GPIO input pin when POL = 0. Note that
ALERT is triggered only when the GPIO is configured as an
input, that is, when DIR = 1. ALERT can never be triggered by a
GPIO that is configured as an output, that is, DIR = 0.
ALERT Output
The ALERT pin is an alarm or interrupt output that goes low, if
any one of a number of interrupt sources is asserted. The results
of high and low limit comparisons on the AUX1, BAT1, BAT2,
and TEMP1 channels are interrupt sources. An out-of-limit
comparison sets a status bit in the alert status/mask register
(Address 00011b).There are separate status bits for both the
high and low limits on each channel to indicate which limit was
exceeded. The interrupt sources can be masked out by clearing
the corresponding enable bit in this register. There is one enable
bit per channel.
ALERT is also asserted, if an input on a GPIO pin sets a bit in
the GPIO data register, as explained in the previous section.
GPIO interrupts can be disabled by clearing the corresponding
ALEN bit in the GPIO control registers.
When DIR = 1, the pin is an input. An input value on the
relevant GPIO pin sets or clears the corresponding bit in the
GPIO data register, depending on the POL bit. A GPIO data
register bit is read-only when DIR = 1 for that GPIO.
Polarity—POL
When POL = 0, the GPIO pin is active low. When POL = 1, the
GPIO pin is active high. How this bit affects the GPIO operation also depends on the DIR bit.
If POL = 1 and DIR = 1, a 1 at the input pin sets the corresponding GPIO data register bit to 1. A 0 at the input pin clears
the corresponding GPIO data bit to 0.
The interrupt source can be identified by reading the GPIO data
register and the alert status/enable register. ALERT remains
asserted until the source of the interrupt has been masked out
or removed.
If the ALERT source is a GPIO, then masking out the interrupt
by clearing the corresponding ALEN bit to 0 or removing the
source of the interrupt on the GPIO pin causes ALERT to go
high again.
Rev. A | Page 30 of 44
AD7877
If the ALERT source is an out-of-limit measurement, writing a 0
to the corresponding status bit in the alert status/enable register
causes ALERT to go high. However, the status bit is set to 1
again on the next measurement cycle, if the measurement
remains out of limit. The ALERT source can also be masked by
clearing the relevant bit in the alert status/enable register to 0.
Table 12. GPIO Configuration
EN
DIR
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
POL
X
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
Data Bit1
ALEN
X
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
X
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
X
0
1
0
1
0
1
0
1
1
0
1
0
0
1
0
1
Shaded data values indicate that a change in input voltage on the pin causes a change in the data register bit.
Shaded pin voltage values indicate that a change in the data register causes a change in the output voltage on the pin.
Rev. A | Page 31 of 44
Pin Voltage2
X
1
0
1
0
0
1
0
1
0
1
0
1
0
1
0
1
ALERT
X
1
1
1
1
1
1
1
1
1
1
0
1
1
1
1
0
AD7877
GROUNDING AND LAYOUT
It is recommended that the ground pins, AGND and DGND, be
shorted together as close as possible to the device itself on the
user’s PCB.
The bottom of the chip scale package has a central thermal pad.
The thermal pad on the printed circuit board should be at least
as large as this exposed pad. On the printed circuit board, there
should be a clearance of at least 0.25 mm between the thermal
pad and the inner edges of the pad pattern. This ensures that
shorting is avoided.
For more information on grounding and layout considerations
for the AD7877, refer to the Layout and Grounding Recommendations for Touch Screen Digitizers Technical Note.
Thermal vias can be used on the printed circuit board thermal
pad to improve thermal performance of the package. If vias are
used, they should be incorporated in the thermal pad at a
1.2 mm pitch grid. The via diameter should be between 0.3 mm
and 0.33 mm and the via barrel should be plated with 1 oz.
copper to plug the via.
PCB DESIGN GUIDELINES FOR CHIP SCALE
PACKAGES
The lands on the chip scale package (CP-32) are rectangular.
The printed circuit board pad for these should be 0.1 mm
longer than the package land length and 0.05 mm wider than
the package land width. The land should be centered on the pad.
This ensures that the solder joint size is maximized.
The user should connect the printed circuit board thermal pad
to AGND.
TO LCD
BACKLIGHT
VIN
OUT
FB
DC-DC
CONVERTER
RRNG
NC
HOST
INT1
ALERT 22
AD7877
INT2
GPIO
4
AUX3/GPIO3
5
AUX2/GPIO2
STOPACQ 20
MISO
6
AUX1/GPIO1
DIN 19
MOSI
7
VCC
8
NC
GPIO4 21
AGND
DGND
9
10
11
12
13
14
15
PENIRQ 17
SCLK
CS
PENIRQ
NC
Y+
CS 18
X+
1.0µF–10µF
(OPTIONAL)
NC 24
DAV 23
Y–
16
HSYNC SIGNAL
FROM LCD
NC = NO CONNECT
TOUCH
SCREEN
Figure 47. Typical Application Circuit
Rev. A | Page 32 of 44
03796-026
TEMPERATURE
MEASUREMENT
DIODE
25
DCLK
BAT1
26
DOUT
3
27
ARNG
BAT2
28
VDRIVE
NC
2
0.1µF
MAIN
BATTERY
VREF
1
29
X–
VOLTAGE
REGULATOR
30
SPI
INTERFACE
FROM AUDIO
REMOTE CONTROL
FROM
HOTSYNC INPUTS
31
NC
SECONDARY
BATTERY
32
AOUT
0.1µF
NC
VCC
AD7877
REGISTER MAPS
Table 13. Write Register Map
WADD3
0
0
Register Address
Binary
WADD2 WADD1 WADD0
0
0
0
0
0
1
HEX
0
1
Register Name
None
Control Register 1
0
0
1
0
2
Control Register 2
0
0
1
1
3
0
0
0
0
1
1
1
1
1
1
1
1
1
0
0
0
0
1
0
0
1
1
0
0
1
1
0
0
1
0
1
0
1
0
1
0
4
5
6
7
8
9
A
B
C
1
1
0
1
D
1
1
1
1
1
1
0
1
E
F
Alert
Status/Enable
Register
AUX1 High Limit
AUX1 Low Limit
BAT1 High Limit
BAT1 Low Limit
BAT2 High Limit
BAT2 Low Limit
TEMP1 Low Limit
TEMP1 High Limit
Sequencer
Register 0
Sequencer
Register 1
DAC Register
Extended Write
Description
Unused. Writing to this address has no effect.
Contains ADC channel address, register read address, and ADC
mode.
Contains ADC averaging, acquisition time, power management, first conversion delay, STOPACQ polarity, and reference
and timer settings.
Contains status of high/low limit comparisons for TEMP1, BAT1,
BAT2, and AUX1, and enable bits to allow these channels to
become interrupt sources.
User-programmable AUX1 upper limit.
User-programmable AUX1 lower limit.
User-programmable BAT1 upper limit.
User-programmable BAT1 lower limit.
User-programmable BAT2 upper limit.
User-programmable BAT2 lower limit.
User-programmable TEMP1 lower limit.
User-programmable TEMP1 upper limit.
Contains channel selection data for slave mode (software)
sequencing.
Contains channel selection data for master mode (hardware)
sequencing.
Contains DAC data and setup information.
Not a physical register. Enables writing to extended writing
map.
Table 14. Extended Writing Map
EADD3
0
Register Address
Binary
EADD2
EADD1
EADD0
0
0
0
HEX
0
0
0
0
1
1
0
0
1
0
2
Register Name
GPIO Control
Register 1
GPIO Control
Register 2
GPIO Data
Description
Contains polarity, direction, enabling, and interrupt enabling
settings for GPIO1 and GPIO2.
Contains polarity, direction, enabling, and interrupt enabling
settings for GPIO3 and GPIO4.
Contains GPIO1 to GPIO4 data.
Rev. A | Page 33 of 44
AD7877
Table 15. Read Register Map
RADD4
0
0
0
0
RADD3
0
0
0
0
Register Address
Binary
RADD2 RADD1
0
0
0
0
0
1
0
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
04
05
06
07
08
09
0A
0B
0C
0D
0E
0F
10
11
12
Register Name
None
Control Register 1
Control Register 2
Alert Status/Enable
Register
AUX1 High Limit
AUX1 Low Limit
BAT1 High Limit
BAT1 Low Limit
BAT2 High Limit
BAT2 Low Limit
TEMP1 Low Limit
TEMP1 High Limit
Sequencer Register 0
Sequencer Register 1
DAC Register
None
X+
Y+
Y− (Z2)
1
1
1
1
1
1
1
1
0
0
0
0
0
1
1
1
0
1
1
1
1
0
0
0
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
13
14
15
16
17
18
19
1A
AUX1
AUX2
AUX3
BAT1
BAT2
TEMP1
TEMP2
X+ (Z1)
1
1
0
1
1
1B
1
1
1
0
0
1C
1
1
1
1
1
1
1
1
1
0
1
1
1
0
1
1D
1E
1F
GPIO Control
Register 1
GPIO Control
Register 2
GPIO Data Register
None
None
RADD0
0
1
0
1
HEX
00
01
02
03
Rev. A | Page 34 of 44
Description
Reads back all zeros.
See Table 13.
See Table 13.
See Table 13.
See Table 13.
See Table 13.
See Table 13.
See Table 13.
See Table 13.
See Table 13.
See Table 13.
See Table 13.
See Table 13.
See Table 13.
See Table 13.
Factory use only.
Measurement at X+ input for Y position.
Measurement at Y+ input for X position.
Measurement at Y− input for touch-pressure
calculation Z2.
Auxiliary Input 1 measurement.
Auxiliary Input 2 measurement.
Auxiliary Input 3 measurement.
Battery Input 1 measurement.
Battery Input 1 measurement.
Single-ended temperature measurement.
Differential temperature measurement.
Measurement at X+ input for touch-pressure
calculation Z1.
See Table 13.
See Table 13.
See Table 13.
Factory use only.
Factory use only.
AD7877
DETAILED REGISTER DESCRIPTIONS
Register Name: Control Register 1
Write Address: 0001; Read Address: 00001; Default Value: 0x000; Type: Read/Write.
Table 16.
Bit
0
1
Name
MODE0
MODE1
Read/
Write
R/W
R/W
2
3
4
5
6
7
8
9
10
RD0
RD1
RD2
RD3
RD4
CHADD0
CHADD1
CHADD2
CHADD3
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
11
SER/DFR
R/W
Description
LSB of ADC mode code
MSB of ADC mode code
00 = No conversion
01 = Single conversion
10 = Conversion sequence (slave mode)
11 = Conversion sequence (master mode)
LSB of register read address. To read a register, its address must first be written to Control Register 1.
Bit 1 of register read address. To read a register, its address must first be written to Control Register 1.
Bit 2 of register read address. To read a register, its address must first be written to Control Register 1.
Bit 3 of register read address. To read a register, its address must first be written to Control Register 1.
MSB of register read address. To read a register, its address must first be written to Control Register 1.
LSB of ADC channel address
Bit 1 of ADC channel address
Bit 2 of ADC channel address
MSB of ADC channel address
0000 = X+ input (Y position)
0001 = Y+ input (X position)
0010 = Y− (Z2) input (used for touch-pressure calculation)
0011 = Auxiliary Input 1 (AUX1)
0100 = Auxiliary Input 2 (AUX2)
0101 = Auxiliary Input 3 (AUX3)
0110 = Battery Monitor Input 1 (BAT1)
0111 = Battery Monitor Input 2 (BAT2)
1000 = Temperature Measurement 1 (used for single conversion)
1001 = Temperature Measurement 2 (used for differential measurement method)
1010 = X+ (Z1) input (used for touch-pressure calculation)
Selects normal (single-ended) or ratiometric (differential) conversion
0 = Ratiometric (differential)
1 = Normal (single-ended)
Rev. A | Page 35 of 44
AD7877
Register Name: Control Register 2
Write Address: 0010; Read Address: 00010; Default Value: 0x000.
Table 17.
Bit
0
1
Name
TMR0
TMR1
Read/
Write
R/W
R/W
2
REF
R/W
3
POL
R/W
4
5
FCD0
FCD1
R/W
R/W
6
7
PM0
PM1
R/W
R/W
8
9
ACQ0
ACQ1
R/W
R/W
10
11
AVG0
AVG1
R/W
R/W
Description
LSB of conversion interval timer
MSB of conversion interval timer
00 = Convert only once
01 = Every 1024 clock periods (512 µs)
10 = Every 2048 clock periods (1.024 ms)
11 = Every 16384 clock periods (8.19 ms)
Selects internal or external reference
0 = Internal reference
1 = External reference
Indicates polarity of signal on STOPACQ pin
0 = Active low
1 = Active high
LSB of first conversion delay
MSB of first conversion delay
This delay occurs before the first conversion after powering up the ADC, before converting the X and Y
coordinate channels to allow settling, and after the last conversion to allow PENIRQ precharge.
00 = 1 clock period delay (500 ns)
01 = 256 clock periods delay (128 µs)
10 = 2048 clock periods delay (1.024 ms)
11 = 16384 clock periods delay (8.19 ms)
LSB of ADC power management code
MSB of ADC power management code
00 = ADC and reference powered down continuously
01 = ADC and reference* powered down when not converting
10 = ADC and reference* powered up continuously
11 = ADC powered down when not converting, reference* powered up
*Irrespective of PM bits, reference is always powered down, if REF bit is 1.
LSB of ADC acquisition time
MSB of ADC acquisition time
00 = 4 clock periods (2 µs)
01 = 8 clock periods (4 µs)
10 = 16 clock periods (8 µs)
11 = 32 clock periods (16 µs)
LSB of ADC averaging code
MSB of ADC averaging code
00 = No averaging (1 conversion per channel)
01 = 4 measurements per channel averaged
10 = 8 measurements per channel averaged
11 = 16 measurements per channel averaged
Rev. A | Page 36 of 44
AD7877
Register Name: Alert Status/Enable Register
Write Address: 0011; Read Address: 00011; Default Value: 0x000.
Table 18.
Bit
0
1
2
3
4
5
6
7
8
Name
AUX1LO
BAT1LO
BAT2LO
TEMP1HI
AUX1HI
BAT1HI
BAT2HI
TEMP1LO
AUX1EN
Read/
Write
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Description
When this bit is 1, the AUX1 channel is below its low limit.
When this bit is 1, the BAT1 channel is below its low limit.
When this bit is 1, the BAT2 channel is below its low limit.
When this bit is 1, the TEMP1 channel is below its high limit.
When this bit is 1, the AUX1 channel is above its high limit.
When this bit is 1, the BAT1 channel is above its high limit.
When this bit is 1, the BAT2 channel is above its high limit.
When this bit is 1, the TEMP1 channel is above its low limit.
Setting this bit enables AUX1 as an interrupt source to the ALERT output.
9
BAT1EN
R/W
Setting this bit enables BAT1 as an interrupt source to the ALERT output.
10
BAT2EN
R/W
Setting this bit enables BAT2 as an interrupt source to the ALERT output.
11
TEMP1EN
R/W
Setting this bit enables TEMP1 as an interrupt source to the ALERT output.
Register Name: AUX1 High Limit
Write Address: 0100; Read Address: 00100; Default Value: 0x000; Type: Read/Write.
This register contains the 12-bit high limit for Auxiliary Input 1.
Register Name: AUX1 Low Limit
Write Address: 0101; Read Address: 00101; Default Value: 0x000; Type: Read/Write.
This register contains the 12-bit low limit for Auxiliary Input 1.
Register Name: BAT1 High Limit
Write Address: 0110; Read Address: 00110; Default Value: 0x000; Type: Read/Write.
This register contains the 12-bit high limit for Battery Monitoring Input 1.
Register Name: BAT1 Low Limit
Write Address: 0111; Read Address: 00111; Default Value: 0x000; Type: Read/Write.
This register contains the 12-bit low limit for Battery Monitoring Input 1.
Register Name: BAT2 High Limit
Write Address: 1000; Read Address: 01000; Default Value: 0x000; Type: Read/Write.
This register contains the 12-bit high limit for Battery Monitoring Input 2.
Register Name: BAT2 Low Limit
Write Address: 1001; Read Address: 01001; Default Value: 0x000; Type: Read/Write.
This register contains the 12-bit low limit for Battery Monitoring Input 2.
Register Name: TEMP1 Low Limit
Write Address: 1010; Read Address: 01010; Default Value: 0x000; Type: Read/Write.
This register contains the 12-bit low limit for temperature measurement.
Register Name: TEMP1 High Limit
Write Address: 1011; Read Address: 01011; Default Value: 0x000; Type: Read/Write.
This register contains the 12-bit high limit for temperature measurement.
Rev. A | Page 37 of 44
AD7877
Register Name: Sequencer Register 0
Write Address: 1100; Read Address: 01100; Default Value: 0x000.
Table 19.
Bit
0
1
2
3
Name
Not Used
Z1_SS
TEMP2_SS
TEMP1_SS
Read/
Write
R/W
R/W
R/W
R/W
4
5
6
7
8
9
10
11
BAT2_SS
BAT1_SS
AUX3_SS
AUX2_SS
AUX1_SS
Z2_SS
XPOS_SS
YPOS_SS
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Description
This bit is not used.
Setting this bit includes the Z1 touch-pressure measurement (X+ input) in a slave mode sequence.
Setting this bit includes a temperature measurement using differential conversion in a slave mode sequence.
Setting this bit includes a temperature measurement using single-ended conversion in a slave mode
sequence.
Setting this bit includes measurement of Battery Monitor Input 2 in a slave mode sequence.
Setting this bit includes measurement of Battery Monitor Input 1 in a slave mode sequence.
Setting this bit includes measurement of Auxiliary Input 3 in a slave mode sequence.
Setting this bit includes measurement of Auxiliary Input 2 in a slave mode sequence.
Setting this bit includes measurement of Auxiliary Input 1 in a slave mode sequence.
Setting this bit includes the Z2 touch-pressure measurement (Y− input) in a slave mode sequence.
Setting this bit includes measurement of the X position (Y+ input) in a slave mode sequence.
Setting this bit includes measurement of the Y position (X+ input) in a slave mode sequence.
Register Name: Sequencer Register 1
Write Address: 1101; Read Address: 01101; Default Value: 0x000.
Table 20.
Bit
0
1
2
Name
Not Used
Z1_MS
TEMP2_MS
Read/
Write
R/W
R/W
R/W
3
TEMP1_MS
R/W
4
5
6
7
8
9
10
11
BAT2_MS
BAT1_MS
AUX3_MS
AUX2_MS
AUX1_MS
Z2_MS
XPOS_MS
YPOS_MS
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Description
This bit is not used.
Setting this bit includes the Z1 touch-pressure measurement (X+ input) in a master mode sequence.
Setting this bit includes a temperature measurement using differential conversion in a master mode
sequence.
Setting this bit includes a temperature measurement using single-ended conversion in a master mode
sequence.
Setting this bit includes measurement of Battery Monitor Input 2 in a master mode sequence.
Setting this bit includes measurement of Battery Monitor Input 1 in a master mode sequence.
Setting this bit includes measurement of Auxiliary Input 3 in a master mode sequence.
Setting this bit includes measurement of Auxiliary Input 2 in a master mode sequence.
Setting this bit includes measurement of Auxiliary Input 1 in a master mode sequence.
Setting this bit includes the Z2 touch-pressure measurement (Y− input) in a master mode sequence.
Setting this bit includes measurement of the X position (Y+ input) in a master mode sequence.
Setting this bit includes measurement of the Y position (X+ input) in a master mode sequence.
Rev. A | Page 38 of 44
AD7877
Register Name: DAC Register
Write Address: 1110; Read Address: 01110; Default Value: 0x000.
Table 21.
Bit
0
Name
RANGE
Read/
Write
R/W
1
2
Not Used
V/I
R/W
R/W
3
PD
R/W
4
5
6
7
8
9
10
11
DAC0
DAC1
DAC2
DAC3
DAC4
DAC5
DAC6
DAC7
Description
Output range of the DAC in voltage mode
0 = 0 to VCC/2
1 = 0 to VCC
This bit is not used.
Voltage output and current output
0 = Voltage
1 = Current
DAC power-down
0 = DAC on
1 = DAC powered down
LSB of DAC data
Bit 1 of DAC data
Bit 2 of DAC data
Bit 3 of DAC data
Bit 4 of DAC data
Bit 5 of DAC data
Bit 6 of DAC data
MSB of DAC data
Register Name: Y Position
Write Address: N/A; Read Address: 10000; Default Value: 0x000; Type: Read Only.
This register contains the 12-bit result of the measurement at the X+ input with Y layer excited (Y position measurement).
Register Name: X Position
Write Address: N/A; Read Address: 10001; Default Value: 0x000; Type: Read Only.
This register contains the 12-bit result of the measurement at the Y+ input with X layer excited (X position measurement).
Register Name: Z2
Write Address: N/A; Read Address: 10010; Default Value: 0x000; Type: Read Only.
This register contains the 12-bit result of the measurement at the Y− input with excitation voltage applied to Y+ and X− (used for touchpressure calculation).
Register Name: AUX1
Write Address: N/A; Read Address: 10011; Default Value: 0x000; Type: Read Only.
This register continues the 12-bit result of the measurement at Auxiliary Input 1.
Register Name: AUX2
Write Address: N/A; Read Address: 10100; Default Value: 0x000; Type: Read Only.
This register continues the 12-bit result of the measurement at Auxiliary Input 2.
Register Name: AUX3
Write Address: N/A; Read Address: 10101; Default Value: 0x000; Type: Read Only.
This register continues the 12-bit result of the measurement at Auxiliary Input 3.
Rev. A | Page 39 of 44
AD7877
Register Name: BAT1
Write Address: N/A; Read Address: 10110; Default Value: 0x000; Type: Read Only.
This register continues the 12-bit result of the measurement at Battery Monitor Input 1.
Register Name: BAT2
Write Address: N/A; Read Address: 10111; Default Value: 0x000; Type: Read Only.
This register continues the 12-bit result of the measurement at Battery Monitor Input 2.
Register Name: TEMP1
Write Address: N/A; Read Address: 11000; Default Value: 0x000; Type: Read Only.
This register continues the 12-bit result of a temperature measurement using single-ended conversion.
Register Name: TEMP2
Write Address: N/A; Read Address: 11001; Default Value: 0x000; Type: Read Only.
This register continues the 12-bit result of a temperature measurement using a differential conversion.
Register Name: Z1
Write Address: N/A; Read Address: 11010; Default Value: 0x000; Type: Read Only.
This register continues the 12-bit result of a measurement at the X+ input with excitation voltage applied to Y+ and X− (used for touchpressure calculation).
Rev. A | Page 40 of 44
AD7877
GPIO REGISTERS
GPIO registers are written to using an extended 8-bit address.
The first four bits of the data-word are always 1111b to access
the extended writing map. The next four bits are the register
address. This leaves 8 bits for the GPIO data.
GPIO registers are read like all other registers, by writing a 5-bit
address to Control Register 1, then reading DOUT.
See the GPIO Configuration section for information on
configuring the GPIOs.
Register Name: GPIO Control Register 1
Write Address: [1111] 0000; Read Address: 11011; Default Value: 0x000.
Table 22.
Bit
0
Name
GPIO2_ALEN
Read/
Write
R/W
1
GPIO2_DIR
R/W
2
GPIO2_POL
R/W
3
GPIO2_EN
R/W
4
GPIO1_ALEN
R/W
5
GPIO1_DIR
R/W
6
GPIO1_POL
R/W
7
GPIO1_EN
R/W
Description
If this bit is 1, GPIO2 is an interrupt source for the ALERT output.
Clearing this bit masks out GPIO2 as an interrupt source for the ALERT output.
This bit sets the direction of GPIO2.
0 = Output
1 = Input
This bit determines if GPIO2 is active high or low.
0 = Active low
1 = Active high
This bit selects the function of AUX2/GPIO2.
0 = AUX2
1 = GPIO2
If this bit is 1, GPIO1 is an interrupt source for the ALERT output.
Clearing this bit masks out GPIO1 as an interrupt source for the ALERT output.
This bit sets the direction of GPIO1.
0 = Output
1 = Input
This bit determines if GPIO1 is active high or low.
0 = Active low
1 = Active high
This bit selects the function of AUX1/GPIO1.
0 = AUX1
1 = GPIO1
Rev. A | Page 41 of 44
AD7877
Register Name: GPIO Control Register 2
Write Address: [1111] 0001; Read Address: 11100; Default Value: 0x000.
Table 23.
Bit
0
Name
GPIO4_ALEN
Read/
Write
R/W
1
GPIO4_DIR
R/W
2
GPIO4_POL
R/W
3
4
Not Used
GPIO3_ALEN
R/W
5
GPIO3_DIR
R/W
6
GPIO3_POL
R/W
7
GPIO3_EN
R/W
Description
If this bit is 1, GPIO4 is an interrupt source for the ALERT output.
Clearing this bit masks out GPIO3 as an interrupt source for the ALERT output.
This bit sets the direction of GPIO4.
0 = Output
1 = Input
This bit determines if GPIO4 is active high or low.
0 = Active low
1 = Active high
This bit is not used.
If this bit is 1, GPIO3 is an interrupt source for the ALERT output.
Clearing this bit masks out GPIO4 as an interrupt source for the ALERT output.
This bit sets the direction of GPIO3.
0 = Output
1 = Input
This bit determines if GPIO3 is active high or low.
0 = Active low
1 = Active high
This bit selects the function of AUX3/GPIO3.
0 = AUX3
1 = GPIO3
Register Name: GPIO Data Register
Write Address: [1111] 0010; Read Address: 11101; Default Value: 0x000.
Table 24.
Bit
0
1
2
3
4
5
6
7
Name
Not Used
Not Used
Not Used
Not Used
GPIO4_DAT
GPIO3_DAT
GPIO2_DAT
GPIO1_DAT
Read/
Write
R/W
R/W
R/W
R/W
Description
This bit is not used.
This bit is not used.
This bit is not used.
This bit is not used.
GPIO4 data bit.
GPIO3 data bit.
GPIO2 data bit.
GPIO1 data bit.
Rev. A | Page 42 of 44
AD7877
OUTLINE DIMENSIONS
0.60 MAX
5.00
BSC SQ
0.60 MAX
PIN 1
INDICATOR
TOP
VIEW
0.50
BSC
4.75
BSC SQ
0.50
0.40
0.30
12° MAX
1.00
0.85
0.80
PIN 1
INDICATOR
32
25
24
1
3.25
3.10 SQ
2.95
EXPOSED
PAD
(BOTTOM VIEW)
17
16
9
8
0.25 MIN
3.50 REF
0.80 MAX
0.65 TYP
0.05 MAX
0.02 NOM
SEATING
PLANE
0.30
0.23
0.18
0.20 REF
COPLANARITY
0.08
COMPLIANT TO JEDEC STANDARDS MO-220-VHHD-2
Figure 48. 32-Lead Lead Frame Chip Scale Package [LFCSP]
5 mm × 5 mm Body
(CP-32-2)
Dimensions shown in millimeters
ORDERING GUIDE
Model
AD7877ACP-REEL
AD7877ACP-REEL7
AD7877ACP-500RL7
AD7877ACPZ-REEL1
AD7877ACPZ-REEL7 1
AD7877ACPZ-500RL71
EVAL-AD7877EB
1
Operating Temperature Range
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
Z = Pb-free part.
Rev. A | Page 43 of 44
Package Description
32-Lead LFCSP
32-Lead LFCSP
32-Lead LFCSP
32-Lead LFCSP
32-Lead LFCSP
32-Lead LFCSP
Evaluation Board
Package Option
CP-32-2
CP-32-2
CP-32-2
CP-32-2
CP-32-2
CP-32-2
AD7877
NOTES
© 2004 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D03796–0–11/04(A)
Rev. A | Page 44 of 44
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