2009-2016 Microchip Technology Inc. DS40001393C-page 1
S pecial Features
RoHS Compliant
Power-Saving Sleep mode
Industrial Temperature Range
Built-in Drift Compensation Algorithm
128 Bytes of User EEPROM
Power Requirements
Operating Voltage: 2.5-5.0V ±5%
Standby Current:
- 5V: 85 µA, typical; 125 µA (maximum)
- 2.5V: 40 µA, typical; 60 µA (maximum)
Operating “No touch” Current:
- 3.0 mA (typical)
Operating “Touch” Current:
- 17 mA, typical, with a touch sensor having
200 layers
- Actual current is dependent on the touch
sensor used
AR1011/AR1021 Brown-Out Detection (BOR) set
to 2.2V
Touch Modes
Off, Stream, Down, Up and more.
Touch Sensor Support
4-Wire, 5-Wire and 8-Wire Analog Resistive
Lead-to-Lead Resistance: 50-2,000typical)
Layer-to-Layer Capacitance: 0-0.5 µF
Touch Sensor Time Constant: 500 µs (maximum)
Touch Resolution
10-bit Resolution (maximum)
Touch Coordinate Report Rate
140 Reports Per Second (typical) with a Touch
Sensor of 0.02 µF with 200 Layers
Actual Report Rate is dependent on the Touch
Sensor used
Communications
SPI, Slave mode, p/n AR1021
•I
2C, Slave mode, p/n, AR1021
UART, 9600 Baud Rate, p/n AR1011
AR1000 SERIES RESISTIVE TOUCH
SCREEN CONTROLLER
AR1000 Series Resistive Touch Screen Contr o ller
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 2 2009-2016 Microchip Technology Inc.
Table of Contents
1.0 Device Overview .......................................................................................................................................................................... 3
2.0 Basics of Resistive Sensors ......................................................................................................................................................... 5
3.0 Hardware...................................................................................................................................................................................... 9
4.0 I2C Communications .................................................................................................................................................................. 14
5.0 SPI Communications .................................................................................................................................................................. 18
6.0 UART Communications .............................................................................................................................................................. 22
7.0 Touch Reporting Protocol ........................................................................................................................................................... 23
8.0 Configuration Registers.............................................................................................................................................................. 24
9.0 Commands ................................................................................................................................................................................. 30
10.0 Application Notes ....................................................................................................................................................................... 39
11.0 Electrical Specifications.............................................................................................................................................................. 45
12.0 Packaging Information................................................................................................................................................................ 47
Appendix A: Data Sheet Revision History............................................................................................................................................ 57
Appendix B: Device Differences........................................................................................................................................................... 58
The Microchip Website......................................................................................................................................................................... 59
Customer Change Notification Service ................................................................................................................................................ 59
Customer Support ................................................................................................................................................................................ 59
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2009-2016 Microchip Technology Inc. DS40001393C-page 3
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
1.0 DEVICE OVERVIEW
The Microchip mTouch® AR1000 Series Resistive
Touch Screen Controller is a complete, easy to
integrate, cost-effective and universal touch screen
controller chip.
The AR1000 Series has sophisticated proprietary
touch screen decoding algorithms to process all touch
data, saving the host from the processing overhead.
Providing filtering capabilities beyond that of other
low-cost devices, the AR1000 delivers reliable,
validated, and calibrated touch coordinates.
Using the on-board EEPROM, the AR1000 can store
and independently apply the calibration to the touch
coordinates before sending them to the host. This
unique combination of features makes the AR1000 the
most resource-efficient touch screen controller for
system designs, including embedded system
integrations.
1.1 Applications
The AR1000 Series is designed for high volume, small
form factor touch solutions with quick time to market
requirements – including, but not limited to:
Mobile communication devices
Personal Digital Assistants (PDA)
Global Positioning Systems (GPS)
Touch Screen Monitors
•KIOSK
Media Players
Portable Instruments
Point of Sale Terminals
FIGURE 1-1: BLOCK DIAGRAM
FIGURE 1-2: PIN DIAGRAM
20
19
18
17
16
15
14
13
12
11
VSS
X-
X+
5WSX-
Y-
Y+
SX+
SDI/SDA/RX
NC
SCK/SCL/TX
1
2
3
4
5
6
7
8
9
10
VDD
M1
SY-
M2
WAKE
SIQ
SY+
SS
SDO
NC
AR1000 Series (SSOP, SOIC)
20
19
18
17
16
15
14
13
12
11
X+
5WSX-
Y-
Y+
SX+
1
2
3
4
5
6
7
8
9
10
SY-
M1
M2
WAKE
SIQ
SY+
SS
VDD
VSS
X-
SDO
NC
SCK/SCL/TX
NC
SDI/SDA/RX
AR1000 Series (QFN)
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 4 2009-2016 Microchip Technology Inc.
TABLE 1-1: PIN DESCRIPTIONS
Pin Function Description/Comments
SSOP, SOIC QFN
118 V
DD Supply Voltage
2 19 M1 Communication Selection
3 20 SY- Sense Y- (8-wire). Tie to VSS, if
not used.
4 1 M2 4/8-wire or 5-wire Sensor
Selection
5 2 WAKE Touch Wake-up/Touch Detection
6 3 SIQ LED Drive/SPI Interrupt. No
connect, if not used.
7 4 SY+ Sense Y+ (8-wire). Tie to VSS, if
not used.
8 5 SS Slave Select (SPI). Tie to VSS, if
not used.
9 6 SDO SPI Serial Data Output/I2C
Interrupt. Tie to Vss, if UART.
10 7 NC No connection. No connect or tie
to VSS or VDD.
11 8 SCK/SCL/TX SPI/I2C Serial Clock/UART
Transmit
12 9 NC No connection. No connect or tie
to VSS or VDD.
13 10 SDI/SDA/RX I2C Serial Data/SPI Serial Data
Input/UART Receive
14 11 SX+ Sense X+ (8-wire). Tie to VSS, if
not used.
15 12 Y+ Y+ Drive
16 13 Y- Y- Driv e
17 14 5WSX- 5W Sense (5-wire)/Sense X-
(8-wire). Tie to VSS, if not used.
18 15 X+ X+ Drive
19 16 X- X- Drive
20 17 VSS Supply Voltage Ground
2009-2016 Microchip Technology Inc. DS40001393C-page 5
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
2.0 BASICS OF RESISTIVE
SENSORS
2.1 Terminology
ITO (Indium Tin Oxide) is the resistive coating that
makes up the active area of the touch sensor. ITO is a
transparent semiconductor that is sputtered onto the
touch sensor layers.
Flex or Film or Topsheet is the top sensor layer that a
user touches. Flex refers to the fact that the top layer
physically flexes from the pressure of a touch.
Stable or Glass is the bottom sensor layer that
interfaces against the display.
Spacer Adhesive is a frame of adhesive that connects
the flex and stable layers together around the perimeter
of the sensor.
Spacer Dots maintain physical and electrical
separation between the flex and stable layers. The dots
are typically printed onto the stable layer.
Bus Bars or Silver Frit electrically connect the ITO on
the flex and stable layers to the sensor’s interface tail.
Bus bars are typically screen printed silver ink. They
are typically much lower in resistivity than the ITO.
X-Axis is the left and right direction on the touch sensor.
Y-Axis is the top and bottom direction on the touch
sensor.
Drive Lines supply a voltage gradient across the
sensor.
2.2 General
Resistive 4, 5, and 8-wire touch sensors consist of two
facing conductive layers, held in physical separation
from each other. The force of a touch causes the top
layer to deflect and make electrical contact with the
bottom layer.
Touch position measurements are made by applying a
voltage gradient across a layer or axis of the touch
sensor. The touch position voltage for the axis can be
measured using the opposing layer.
A comparison of typical sensor constructions is shown
below in Tab le 2 -1 .
The AR1000 Series Resistive Touch Screen
Controllers will work with any manufacturers of analog
resistive 4, 5 and 8-wire touch screens. The
communications and decoding are included, allowing
the user the quickest simplest method of interfacing
analog resistive touch screens into their applications.
The AR1000 Series was designed with an
understanding of the materials and processes that
make up resistive touch screens. The AR1000 Series
Touch Controller is not only reliable, but can enhance
the reliability and longevity of the resistive touch
screen, due to its advanced filtering algorithms and
wide range of operation.
TABLE 2-1: SENSOR COMPARISON
Sensor Comments
4-Wire Less expensive than 5-wire or 8-wire
Lower power than 5-wire
More linear (without correction) than
5-wire
Touch inaccuracies occur from flex layer
damage or resistance changes
5-Wire Maintains touch accuracy with flex layer
damage
Inherent nonlinearity often requires touch
data correction
Touch inaccuracies occur from resistance
changes
8-Wire More expensive than 4-wire
Lower power than 5-wire
More linear (without correction) than
5-wire
Touch inaccuracies occur from flex layer
damaged
Maintains touch accuracy with resistance
changes
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 6 2009-2016 Microchip Technology Inc.
2.3 4-Wire Sensor
A 4-wire resistive touch sensor consists of a stable and
flex layer, electrically separated by spacer dots. The
layers are assembled perpendicular to each other. The
touch position is determined by first applying a voltage
gradient across the flex layer and using the stable layer
to measure the flex layer’s touch position voltage. The
second step is applying a voltage gradient across the
stable layer and using the flex layer to measure the
stable layer’s touch position voltage.
The measured voltage at any position across a driven
axis is predictable. A touch moving in the direction of
the driven axis will yield a linearly changing voltage. A
touch moving perpendicular to the driven axis will yield
a relatively unchanging voltage (See Figure 2-1).
FIGURE 2-1: 4-WIRE DECODING
2009-2016 Microchip Technology Inc. DS40001393C-page 7
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
2.4 8-Wire Sensor
An 8-wire resistive touch sensor consists of a stable
and flex layer, electrically separated by spacer dots.
The layers are assembled perpendicular to each other.
The touch position is determined by first applying a
voltage gradient across the flex layer and using the
stable layer to measure the flex layer’s touch position
voltage. The second step is applying a voltage gradient
across the stable layer and using the flex layer to
measure the stable layer’s touch position voltage.
The measured voltage at any position across a driven
axis is predictable. A touch moving in the direction of
the driven axis will yield a linearly changing voltage. A
touch moving perpendicular to the driven axis will yield
a relatively unchanging voltage.
The basic decoding of an 8-wire sensor is similar to a
4-wire. The difference is that an 8-wire sensor has four
additional interconnects used to reference sensor
voltage back to the controller.
A touch system may experience voltage losses due to
resistance changes in the bus bars and connection
between the controller and sensor. The losses can vary
with product use, temperature, and humidity. In a
4-wire sensor, variations in the losses manifest
themselves as error or drift in the reported touch
location. The four additional sense lines found on
8-wire sensors are added to dynamically reference the
voltage to correct for this fluctuation during use (See
Figure 2-2).
FIGURE 2-2: 8-WIRE DECODING
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 8 2009-2016 Microchip Technology Inc.
2.5 5-Wire Sensor
A 5-wire resistive touch sensor consists of a flex and
stable layer, electrically separated by spacer dots. The
touch position is determined by first applying a voltage
gradient across the stable layer in the X-axis direction
and using the flex layer to measure the axis touch posi-
tion voltage. The second step is applying a voltage gra-
dient across the stable layer in the Y-axis direction and
using the flex layer to measure the axis touch position
voltage.
The voltage is not directly applied to the edges of the
active layer, as it is for 4-wire and 8-wire sensors. The
voltage is applied to the corners of a 5-wire sensor.
To measure the X-axis, the left edge of the layer is
driven with 0V (ground), using connections to the upper
left and lower left sensor corners. The right edge is
driven with +5 VDC, using connections to the upper
right and lower right sensor corners.
To measure the Y-axis, the top edge of the layer is
driven with 0V (ground), using connections to the upper
left and upper right sensor corners. The bottom edge is
driven with +5 VDC, using connections to the lower left
and lower right sensor corners.
The measured voltage at any position across a driven
axis is predictable. A touch moving in the direction of
the driven axis will yield a linearly changing voltage. A
touch moving perpendicular to the driven axis will yield
a relatively unchanging voltage (See Figure 2-3).
FIGURE 2-3: 5- Wi re Deco din g
2009-2016 Microchip Technology Inc. DS40001393C-page 9
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
3.0 HARDWARE
3.1 Main Schematic
A main application schematic for the SOIC/SSOP
package pinout is shown in Figure 3-1.
See Figure 1-2 for the QFN package pinout.
FIGURE 3-1: MAIN SCHEMATIC (SOIC/SSOP PACKAGE PINOUT)
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 10 2009-2016 Microchip Technology Inc.
3.2 4, 5, 8-Wire Sensor Selection
The desired sensor type of 4/8-wire or 5-wire is
hardware selectable using pin M2.
If 4/8-wire has been hardware-selected, then the
choice of 4-wire or 8-wire is software-selectable via the
TouchOptions Configuration register.
When 4/8-wire is hardware-selected, the controller
defaults to 4-wire operation. If 8-wire operation is
desired, then the TouchOptions Configuration register
must be changed.
3.3 4-Wire Touch Sensor Int erface
Sensor tail pinouts can vary by manufacturer and part
number. Ensure that both sensor tail pins for one
sensor axis (layer) are connected to the controller’s
X-/X+ pins and the tail pins for the other sensor axis
(layer) are connected to the controller’s Y-/Y+ pins. The
controller’s X-/X+ and Y-/Y+ pin pairs do not need to
connect to a specific sensor axis. The orientation of
controller pins X- and X+ to the two sides of a given
sensor axis is not important. Likewise, the orientation of
controller pins Y- and Y+ to the two sides of the other
sensor axis is not important.
Connections to a 4-wire touch sensor are as follows
(See Figure 3-2).
FIGURE 3-2: 4-WIRE TOUCH SENSOR INTERFACE
Tie unused controller pins 5WSX-, SX+, SY-, and SY+
to VSS.
See Section 3.8 “ESD Considerations” and
Section 3.9 “Noise Considerations” for important
information regarding the capacitance of the controller
schematic hardware.
TABLE 3-1: 4/8-WIRE vs. 5-WIRE
SELECTION
Type M2 pin
4/8-wire VSS
5-wire VDD
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AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
3.4 5-Wire Touch Sensor Int erface
Sensor tail pinouts can vary by manufacturer and part
number. Ensure sensor tail pins for one pair of
diagonally related sensor corners are connected to the
controller’s X-/X+ pins and the tail pins for the other pair
of diagonally related corners are connected to the
controller’s Y-/Y+ pins.
The controller’s X-/X+ and Y-/Y+ pin pairs do not need
to connect to a specific sensor axis. The orientation of
controller pins X- and X+ to the two selected diagonal
sensor corners is not important.
Likewise, the orientation of controller pins Y- and Y+ to
the other two selected diagonal sensor corners is not
important. The sensor tail pin connected to its top layer
must be connected to the controller’s 5WSX- pin.
Connections to a 5-wire touch sensor are shown in
Figure 3-3 below.
FIGURE 3-3: 5-WIRE TOUCH SENSOR INTERFACE
Tie unused controller pins SX+, SY-, and SY+ to VSS.
See “Section 3.8 “ESD Considerations” and
Section 3.9 “Noise Considerations” for important
information regarding the capacitance of the controller
schematic hardware.
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 12 2009-2016 Microchip Technology Inc.
3.5 8-Wire Touch Sensor Int erface
Sensor tail pinouts can vary by manufacturer and part
number. Ensure both sensor tail pins for one sensor
axis (layer) are connected to the controller’s X-/X+ pins
and the tail pins for the other sensor axis (layer) are
connected to the controller’s Y-/Y+ pins.
The controller’s X-/X+ and Y-/Y+ pin pairs do not need
to connect to a specific sensor axis. The orientation of
controller pins X- and X+ to the two sides of a given
sensor axis is not important. Likewise, the orientation of
controller pins Y- and Y+ to the two sides of the other
sensor axis is not important.
The 8-wire sensor differs from a 4-wire sensor in that
each edge of an 8-wire sensor has a secondary
connection brought to the sensor’s tail. These
secondary connections are referred to as “sense” lines.
The controller pins associated with the sense line for an
8-wire sensor contain an ‘S’ prefix in their respective
names. For example, the SY- pin is the sense line
connection associated with the main Y- pin connection.
Consult with the sensor manufacturer’s specification to
determine which member of each edge connected pair
is the special 8-wire “sense” connection. Incorrectly
connecting the sense and excite lines to the controller
will adversely affect performance.
The controller requires that the main and “sense” tail
pin pairs for sensor edges be connected to controller
pin pairs as follows:
Y- and SY-
Y+ and SY+
X- and 5WSX-
X+ and SX+
Connections to a 8-wire touch sensor are shown in
Figure 3-4 below.
FIGURE 3-4: 8-WIRE TOUCH SENSOR INTERFACE
See Section 3.8 “ESD Considerations” and
Section 3.9 “Noise Considerations” for important
information regarding the capacitance of the controller
schematic hardware.
2009-2016 Microchip Technology Inc. DS40001393C-page 13
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
3.6 Status LED
The LED and associated resistor are optional.
FIGURE 3-5: LED SCHEMATIC
The LED serves as a status indicator that the controller
is functioning. It will slow flash when the controller is
running with no touch in progress. It will flicker quickly
(mid-level on) when a touch is in progress.
If the LED is used with SPI communication, then the
LED will be off with no touch and flicker quickly
(mid-level on) when a touch is in progress.
3.7 WAKE Pin
The AR1000’s WAKE pin is described as “Touch
Wake-Up/Touch Detection”. It serves the following
three roles in the controller’s functionality:
Wake-up from touch
Touch detection
Measure sensor capacitance
The application circuit shows a 20 K resistor
connected between the WAKE pin and the X- pin on the
controller chip. The resistor is required for product
operation, based on all three of the above roles.
3.8 ESD Considerations
ESD protection is shown on the 4-wire, 5-wire, and
8-wire interface applications schematics.
The capacitance of alternate ESD diodes may
adversely affect touch performance. A lower
capacitance is better. The PESD5V0S1BA parts shown
in the reference design have a typical capacitance of 35
pF. Test to ensure that selected ESD protection does
not degrade touch performance.
ESD protection is shown in the reference design, but
acceptable protection is dependent on your specific
application. Ensure your ESD solution meets your
design requirements.
3.9 Noise Considerations
Touch sensor filtering capacitors are included in the
reference design.
Note: If the SIQ pin is not used, it must be left as
a No Connect and NOT tied to circuit VDD or
VSS.Warning: Changing the value of the capacitors may
adversely affect performance of the touch system.
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 14 2009-2016 Microchip Technology Inc.
4.0 I2C COMMUNICATION S
The AR1021 is an I2C slave device with a 7-bit address
of 0x4D, supporting up to 400 kHz bit rate.
A master (host) device interfaces with the AR1021.
4.1 I2C Hardware Interface
A summary of the hardware interface pins is shown
below in Tab le 4 -1.
M1 Pin
The M1 pin must be connected to VSS to
configure the AR1021 for I2C communications.
SCL Pin
The SCL (Serial Clock) pin is electrically
open-drain and requires a pull-up resistor,
typically 2.2 K to 10 K, from SCL to VDD.
SCL Idle state is high.
SDA Pin
The SDA (Serial Data) pin is electrically
open-drain and requires a pull-up resistor,
typically 2.2 K to 10 K, from SDA to VDD.
SDA Idle state is high.
Master write data is latched in on SCL rising
edges.
Master read data is latched out on SCL falling
edges to ensure it is valid during the subsequent
SCL high time.
SDO Pin
The SDO pin is a driven output interrupt to the
master.
SDO Idle state is low.
SDO will be asserted high when the AR1021 has
data ready (touch report or command response)
for the master to read.
TABLE 4-1: I2C HARDWARE INTERFACE
AR1021 Pin Description
M1 Connect to VSS to select I2C communications
SCL Serial Clock
SDA Serial Data
SDO Data ready interrupt output to master
2009-2016 Microchip Technology Inc. DS40001393C-page 15
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
4.2 I2C Pin Voltage Level
Characteristics
4.3 Addressing
The AR1021’s device ID 7-bit address is: 0x4D
(0b1001101)
4.4 Master Read Bit Timing
Master read is to receive touch reports and command
responses from the AR1021.
Address bits are latched into the AR1021 on the
rising edges of SCL.
Data bits are latched out of the AR1021 on the
rising edges of SCL.
ACK is presented (by AR1021 for address, by
master for data) on the ninth clock.
The master must monitor the SCL pin prior to
asserting another clock pulse, as the AR1021
may be holding off the master by stretching the
clock.
FIGURE 4-1: I2C MASTER READ BIT TIMING DIAGRAM
Steps
1. SCL and SDA lines are Idle high.
2. Master presents “Start” bit to the AR1021 by
taking SDA high-to-low, followed by taking SCL
high-to-low.
3. Master presents 7-bit Address, followed by a
R/W = 1 (Read mode) bit to the AR1021 on
SDA, at the rising edge of eight master clock
(SCL) cycles.
4. AR1021 compares the received address to its
device ID. If they match, the AR1021
acknowledges (ACK) the master sent address
by presenting a low on SDA, followed by a
low-high-low on SCL.
5. Master monitors SCL, as the AR1021 may be
“clock stretching”, holding SCL low to indicate
that the master should wait.
TABLE 4-2: I2C PIN VOLTAGE LEVEL CHARACTERISTICS
Function Pin Input Output
SCL/SCK SCL/SCK/TX VSS VIL 0.2*VDD
0.8*VDD VIH VDD
SDO SDO VSS VOL(1) (1.2V – 0.15*VDD)(2)
(1.25*VDD – 2.25V)(3) VOH(1) VDD
SDA SDI/SDA/RX VSS VIL 0.2*VDD
0.8*VDD VIH VDD
Open-drain
Note 1: These parameters are characterized but not tested.
2: At 10 mA.
3: At –4 mA.
TABLE 4-3: I2C DEVICE ID ADDRESS
Device ID Address, 7-bit
A7 A6 A5 A4 A3 A2 A1
1001101
TABLE 4-4: I2C DEVICE WRITE ID
ADDRESS
A7 A6 A5 A4 A3 A2 A1 A0
1 0 0 11010 0x9A
TABLE 4-5: I2C DEVICE READ ID
ADDRESS
A7 A6 A5 A4 A3 A2 A1 A0
1 0 0 11011 0x9B
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 16 2009-2016 Microchip Technology Inc.
6. Master receives eight data bits (MSb first)
presented on SDA by the AR1021, at eight
sequential master clock (SCL) cycles. The data
is latched out on SCL falling edges to ensure it
is valid during the subsequent SCL high time.
7. If data transfer is not complete, then:
- Master acknowledges (ACK) reception of the
eight data bits by presenting a low on SDA,
followed by a low-high-low on SCL.
- Go to step 5.
8. If data transfer is complete, then:
- Master acknowledges (ACK) reception of the
eight data bits and a completed data transfer
by presenting a high on SDA, followed by a
low-high-low on SCL.
9. Master presents a “Stop” bit to the AR1021 by
taking SCL low-high, followed by taking SDA
low-to-high.
4.5 Master W rite Bit Ti ming
Master write is to send supported commands to the
AR1021.
Address bits are latched into the AR1021 on the
rising edges of SCL.
Data bits are latched into the AR1021 on the
rising edges of SCL.
ACK is presented by AR1021 on the ninth clock.
The master must monitor the SCL pin prior to
asserting another clock pulse, as the AR1021
may be holding off the master by stretching the
clock.
FIGURE 4-2: I2C MASTER WRITE BIT TIMING DIAGRAM
Steps
1. SCL and SDA lines are Idle high.
2. Master presents “Start” bit to the AR1021 by
taking SDA high-to-low, followed by taking SCL
high-to-low.
3. Master presents 7-bit Address, followed by a
R/W = 0 (Write mode) bit to the AR1021 on
SDA, at the rising edge of eight master clock
(SCL) cycles.
4. AR1021 compares the received address to its
device ID. If they match, the AR1021
acknowledges (ACK) the master sent address
by presenting a low on SDA, followed by a
low-high-low on SCL.
5. Master monitors SCL, as the AR1021 may be
“clock stretching”, holding SCL low to indicate
the master should wait.
6. Master presents eight data bits (MSb first) to the
AR1021 on SDA, at the rising edge of eight
master clock (SCL) cycles.
7. AR1021 acknowledges (ACK) receipt of the
eight data bits by presenting a low on SDA,
followed by a low-high-low on SCL.
8. If data transfer is not complete, then go to step 5.
9. Master presents a “Stop” bit to the AR1021 by
taking SCL low-high, followed by taking SDA
low-to-high.
4.6 Clock St retching
The master normally controls the clock line SCL. Clock
stretching is when the slave device holds the SCL line
low, indicating to the master that it is not ready to
continue the communications.
During communications, the AR1021 may hold off the
master by stretching the clock with a low on SCL.
The master must monitor the slave SCL pin to ensure
the AR1021 is not holding it low, prior to asserting
another clock pulse for transmitting or receiving.
4.7 AR1020 Write Conditions
The AR1020 part does not implement clock stretching
on write conditions.
A 50 us delay is needed before the Stop bit, when
clocking a command to the AR1020.
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AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
4.8 Touch Report Protocol
Touch coordinates, when available, are provided to the
master by the AR1021 in the following protocol (See
Figure 4-3).
FIGURE 4-3: I2C TOUCH REPORT PROTOCOL
Note that the IRQ signal shown above occurs on the
SDO pin of the AR1021.
4.9 Command Protocol
The master issues supported commands to the
AR1021 in the following protocol.
Below is an example of the ENABLE_TOUCH command
(see Figure 4-4).
FIGURE 4-4: I2C COMMAND PROTOCOL
Note that the IRQ shown above occurs on the SDO pin.
0x9A AR1021 Device ID address
0x00 Protocol command byte (send 0x00 for
the protocol command register)
0x55 Header
0x01 Data size
0x12 Command
4.10 Sleep State
Pending communications are not maintained through a
sleep/wake cycle.
If the SDO pin is asserted for a pending touch report or
command response, and the AR1021 enters a Sleep
state, prior to the master performing a read on the data,
then the data is lost.
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5.0 SPI COMMUNICATIONS
SPI operates in Slave mode with an Idle low SCK and
data transmitted on the SCK falling edge.
5.1 SPI Hardware Interface
A summary of the hardware interface pins is shown
below in Tab le 5 -1.
SCK Pin
The AR1021 controller’s SCL/SCK/TX pin
receives Serial Clock (SCK), controlled by the
host.
The Idle state of the SCK should be low.
Data is transmitted on the falling edge of SCK.
SDI Pin
The AR1021 controller’s SDI/SDA/RX pin reads
Serial Data Input (SDI), sent by the host.
SDO Pin
The AR1021 controllers SDO pin presents Serial
Data Output (SDO) to the host.
SIQ Pin
The AR1021 controllers SIQ pin provides an
optional interrupt output from the controller to the
host.
The SIQ pin is asserted high when the controller
has data available (a touch report or a command
response) for the host.
The SIQ pin is deasserted after the host clocks
out the first byte of the data packet.
SS Pin
The AR1021 controller’s SS pin provides optional
“slave select” functionality.
In the ‘inactive’ state, the controller’s SDO pin presents
a high-impedance in order to prevent bus contention
with another device on the SPI bus.
TABLE 5-1: SPI HARDWARE INTERFACE
AR1021 Pin Description
M1 Connect to VDD to select SPI communications
SDI Serial data sent from master
SCK Serial clock from master
SDO Serial data to master SPI
SIQ Interrupt output to master (optional)
SS Slave Select (optional)
Note: The AR1000 Development kit PICkit
Serial Pin 1 is designated for the SIQ
interrupt pin after the firmware updated is
executed for the PICkit.
SS Pin Level AR1021 Select
VSS Active
VDD Inactive
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5.2 SPI Pin Voltage Level
Characteristics
5.3 Data Flow
SPI data is transferred by the host clocking the AR1021
controller’s Serial Clock (SCK) pin.
Each host driven clock cycle simultaneously shifts a bit
of data into and out from the AR1021 controller:
Out from the AR1021 controller’s Serial Data Out
(SDO) line.
Into the AR1021 controller’s Serial Data In (SDI)
line.
The data is shifted Most Significant bit (MSb) first.
If the host clocks data out from the AR1021 controller
when no valid data is available, then a byte value of
0x4d will be presented by the controller.
5.4 Touch Report Protocol
The AR1021 controller’s touch reporting is interrupt
driven:
The AR1021 controller asserts the SIQ interrupt
pin high when it has a touch report ready.
The host clocks out the bytes of the touch report
packet from the AR1021 controller.
The AR1021 controller clears the SIQ interrupt pin
low, after the first byte of the touch report packet
has been clocked out by the host.
The communication protocol for the AR1021 controller
reporting touches to the host as shown below in
Figure 5-1.
FIGURE 5-1: SPI TOUCH REPORT PROTOCOL
TABLE 5-2: SPI PIN VOLTAGE CHARACTERISTICS
Operating Voltage: 2.5V VDD 5.25V
Function Pin Input Output
SCK SCL/SCK/TX VSS VIL 0.2*VDD
0.8*VDD VIH VDD
SDI SDI/SDA/RX VSS VIL 0.2*VDD
0.8*VDD VIH VDD
SDO SDO VSS VOL(1) (1.2V – 0.15*VDD)(2)
(1.25*VDD – 2.25V)(3) VOH(1) VDD
SIQ SIQ VSS VOL(1) (1.2V – 0.15*VDD)(2)
(1.25*VDD – 2.25V)(3) VOH(1) VDD
SS SS VSS VIL 0.2*VDD
0.8*VDD VIH VDD
Note 1: These parameters are characterized but not tested.
2: At 10 mA.
3: At -4 mA.
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5.5 Command Protocol
The AR1021 controller receives commands from the
host as follows:
The host clocks the bytes of a command to the
AR1021 controller.
The AR1021 controller asserts the SIQ interrupt
pin high when it is ready with a response to the
command sent by the host.
The host clocks out the bytes of the command
response from the AR1021 controller.
The AR1021 controller clears the SIQ interrupt pin
low, after the first byte of the command response
has been clocked out by the host.
The communication protocol for the host sending the
ENABLE_TOUCH command to the AR1021 controller is
shown below in Figure 5-2.
FIGURE 5-2: SPI TIMING DIAGRAM – COMMAND PROTOCOL (ENABLE_TOUCH)
5.6 SPI Bit Timing – General
General timing waveforms are shown below in
Figure 5-3.
FIGURE 5-3: SPI GENERAL BIT TIMING WAVEFORM
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5.7 Timing – Bit Details
5.7.1 BIT RATE
The SPI standard does not specify a maximum data
rate for the serial bus. In general, SPI data rates can be
in MHz. Peripherals devices, such as the AR1021
controller, specify their own unique maximum SPI data
rates.
The maximum SPI bit rate for the AR1021 controller is
~900 kHz.
Characterization has been performed at bit rates of ~39
kHz and ~156 kHz.
5.7.2 INTER-BYTE DELAY
The AR1021 controller requires an inter-byte delay of
~50 us. This means the host should wait ~50 us
between the end of clocking a given byte and the start
of clocking the next byte.
5.7.3 BIT TIMING – DETAIL
Characterized timing details are shown below, in
Figure 5-4.
FIGURE 5-4: SPI BIT TIMING – DET AIL
TABLE 5-3: SPI BIT TIMING MIN. AND MAX. VALUES
Parameter Number(1) Parameter Description Min. Max. Units
10 SS (select) to SCK (initial) 500 ns
11 SCK high 550 ns
12 SCK low 550 ns
13 SCK (last) to SS (deselect) 800 ns
14 SDI setup before SCK100 ns
15 SDI hold after SCK100 ns
16 SDO valid after SCK—150ns
17 SDO rise 50 ns
18 SDO fall 50 ns
19 SS (deselect) to SDO High-z 10 50 ns
Note 1: Parameters are characterized, but not tested.
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6.0 UART COMM UNICATIONS
UART communication is fixed at 9600 baud rate, 8N1
format.
Sleep mode will cause the TX line to drop low, which
may appear as a 0x00 byte sent from the controller.
TABLE 6-1: UART HARDWARE INTERFACE
AR1 011 Pin Description
M1 Connect M1 to VDD to select UART communications
TX Transmit to host
RX Receive from host
SDO Connect SDO to VSS
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7.0 TOUCH REPORTING
PROTOCOL
Touch coordinates are sent from the controller to the
host system in a 5-byte data packet, which contains the
X-axis coordinate, Y-axis coordinate, and a “Pen-Up/
Down” touch status.
The range for X-axis and Y-axis coordinates is from 0-
4095 (12-bit). The realized resolution is 1024, and bits
X1:X0 and Y1:Y0 are zeros.
It is recommended that applications be developed to
read the 12-bit coordinates from the packet and use
them in a 12-bit format. This enhances the application
robustness, as it will work with either 10 or 12 bits of
coordinate information.
The touch coordinate reporting protocol is shown below
in Tab le 7 -1.
where:
•P: 0 Pen Up, 1 Pen Down
•R: Reserved
X11-X0: X-axis coordinate
Y11-Y0: Y-axis coordinate
TABLE 7-1: TOUCH COORDINATE REPORTING PROTOCOL
Byte # Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
11RRRRRRP
20X6 X65 X4 X3 X2 X1 X0
300 0 X11 X10 X9 X8 X7
40Y6 Y5 Y4 Y3 Y2 Y1 Y0
500 0 Y11 Y10 Y9 Y8 Y7
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8.0 CONFIGURATION REGISTERS
The Configuration registers allow application-specific
customization of the controller. The default values have
been optimized for most applications and are
automatically used, unless you choose to change
them.
Unique sensors and/or product applications may
benefit from adjustment of Configuration registers.
8.1 Restoring Default Parameters
AR1010/AR1020
The factory default settings for the Configuration
registers can be recovered by writing a value of 0xFF
to address 0x00 of the EEPROM, then cycling power.
AR1011/AR1021
The factory default settings for the Configuration
registers can be recovered by writing a value of 0xFF
to addresses 0x01 and 0x29 of the EEPROM, then
cycling power.
Configuration registers are defined as an Offset value
from the Start address for the register group.
To read or write to a register, do the following:
Issue the REGISTER_START_ADDRESS_RE-
QUEST command to obtain the Start address for
the register group.
Calculate the desired registers absolute address
by adding the register’s Offset value to Start
address for the register group.
Issue the REGISTER_READ or REGISTER_WRITE
command, using the calculated register’s
absolute address.
Note: Although most registers can be
configured for a value ranging from 0 to
255, using a value outside the specified
range for the specific register may
negatively impact performance.
TABLE 8-1: CONFIGURATION REGISTERS
Register Name Address
Offset Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 AR1010/
AR1020
Default
AR1011/
AR1021
Default
<Special Use> 0x00 <Non-Configurable> 0x58 0x58
<Special Use> 0x01 <Non-Configurable> 0x01 0x01
TouchThreshold 0x02 Value of: 0-255 0xC5 0xC5
SensitivityFilter 0x03 Value of: 0-255 0x04 0x04
SamplingFast 0x04 Value of: 1, 2, 4, 8, 16, 32, 64, 128 0x04 0x04
SamplingSlow 0x05 Value of: 1, 2, 4, 8, 16, 32, 64, 128 0x10 0x10
AccuracyFilterFast 0x06 Value of: 1-8 0x02 0x04
AccuracyFilterSlow 0x07 Value of: 1-8 0x08 0x08
SpeedThreshold 0x08 Value of: 0-255 0x04 0x04
<Special Use> 0x09 <Non-Configurable> 0x23 0x23
SleepDelay 0x0A Value of: 0-255 0x64 0x64
PenUpDelay 0x0B Value of: 0-255 0x80 0x80
TouchMode 0x0C PD2 PD1 PD0 PM1 PM0 PU2 PU1 PU0 0xB1 0xB1
TouchOptions 0x0D —48WCCE 0x00 0x00
CalibrationInset 0x0E 0x19 0x19
PenStateReportDelay 0x0F Value of: 0-40 0xC8 0xC8
<Special Use> 0x10 Value of: 0-255 0x03 0x03
TouchReportDelay 0x11 <Non-Configurable> 0x00 0x00
<Special Use> 0x12 Value of: 0-255 0x00 0x00
Warning: Use of invalid register values will yield
unpredictable results.
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8.2 Register Descriptions
8.2.1 TouchThreshold Register (OFFSET
0x02)
The TouchThreshold register sets the threshold for a
touch condition to be detected as a touch. A touch is
detected if it is below the TouchThreshold setting. Too
small of a value might prevent the controller from
accepting a real touch, while too large of a value might
allow the controller to accept very light or false touch
conditions. Valid values are as follows:
0 TouchThreshold 255
8.2.2 SensitivityFilter Register (OFFSET
0x03)
The SensitivityFilter register sets the level of touch
sensitivity. A higher value is more sensitive to a touch
(accepts a lighter touch), but may exhibit a less stable
touch position. A lower value is less sensitive to a touch
(requires a harder touch), but will provide a more stable
touch position. Valid values are as follows:
0 SensitivityFilter 10
8.2.3 SamplingFast Register (OFFSET
0x04)
The SamplingFast register sets the level of touch
measurement sample averaging, when touch
movement is determined to be fast. See the
SpeedThreshold register for information on the touch
movement threshold. A lower value will provide for a
higher touch coordinate reporting rate when touch
movement is fast, but may exhibit more high-frequency
random noise error in the touch position. A higher value
will reduce the touch coordinate reporting rate when
touch movement is fast, but will reduce high-frequency
random noise error in the touch position. Valid values
are as follows:
SamplingFast: <1, 4, 8, 16, 32, 64, 128>
Recommended Values: <4, 8, 16>
Higher values may improve accuracy with some
sensors.
8.2.4 SamplingSlow Register (OFFSET
0x05)
The SamplingSlow register sets the level of touch
measurement sample averaging, when touch
movement is slow. See the SpeedThreshold register for
information on the touch movement threshold. A lower
value will increase the touch coordinate reporting rate
when the touch motion is slow, but may exhibit a less
stable more jittery touch position. A higher value will
decrease the touch coordinate reporting rate when the
touch motion is slow, but will provide a more stable
touch position. Valid values are as follows:
SamplingSlow: 1, 2, 4, 8, 16, 32, 64, 128
8.2.5 AccuracyFilterFast Register (OFFSET
0x06)
The AccuracyFilterFast register sets the level of an
accuracy enhancement filter, used when the touch
movement is fast. See the SpeedThreshold register for
information on the touch movement threshold. A lower
value will provide better touch coordinate resolution
when the touch motion is fast, but may exhibit more
low-frequency noise error in the touch position. A
higher value will reduce touch coordinate resolution
when the touch motion is fast, but will reduce low-
frequency random noise error in the touch position.
Valid values are as follows:
1 AccuracyFilterFast 8
Higher values may improve accuracy with some
sensors.
8.2.6 AccuracyFilterSlow Register
(OFFSET 0x07)
The AccuracyFilterSlow register sets the level of an
accuracy enhancement filter, used when the touch
movement is slow. See the SpeedThreshold register for
information on the touch movement threshold. A lower
value will provide better touch coordinate resolution
when the touch motion is slow, but may exhibit more
low-frequency noise error in the touch position. A
higher value will reduce touch coordinate resolution
when the touch motion is slow, but will reduce low-
frequency random noise error in the touch position.
Valid values are as follows:
1 AccuracyFilterSlow 8
8.2.7 SpeedThreshold Register (OFFSET
0x08)
The SpeedThreshold register sets the threshold for
touch movement to be considered as slow or fast. A
lower value reduces the touch movement speed that
will be considered as fast. A higher value increases the
touch movement speed that will be considered as fast.
Valid values are as follows:
0 SpeedThreshhold 255
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8.2.8 SleepDelay Register (OFFSET 0x0A)
The SleepDelay register sets the time duration with no
touch or command activity that will cause the controller
to enter a low-power Sleep mode. Valid values are as
follows:
0 SleepDelay 255
Sleep Delay Time = SleepDelay * 100 ms; when Sleep-
Delay > 0
A value of zero disables the Sleep mode, such that the
controller will never enter low-power Sleep mode.
A touch event will wake the controller from low-power
Sleep mode and start sending touch reports. Commu-
nications sent to the controller will wake it from the low-
power Sleep mode and initiate action to the command.
8.2.9 PenUpDelay Register (OFFSET
0x0B)
The PenUpDelay register sets the duration of a pen-up
event that the controller will allow, without sending a
pen-up report for the event. The delay time is started
upon detecting a pen-up condition.
If a pen down is reestablished before the delay time
expires, then pen-down reports will continue without a
pen up being sent. This effectively debounces a touch
event in process.
A lower value will make the controller more responsive
to pen ups, but will cause more touch drop outs with a
lighter touch. A higher value will make the controller
less responsive to pen ups, but will reduce the number
of touch drop outs with a lighter touch. Valid values are
as follows:
0 PenUpDelay 255
Pen-up Delay Time PenUpDelay * 240 μs
8.2.10 TouchMode Register (OFFSET 0x0C)
The TouchMode register configures the action taken for
various touch states.
There are three states of touch for the controller’s touch
reporting action which can be independently controlled.
Touch States:
1. Pen Down (initial touch)
User defined 0-3 touch reports, with selectable pen
states.
2. Pen Movement (touch movement after initial
touch)
User defined no-touch reports or streaming touch
reports, with selectable pen states.
3. Pen Up (touch release)
User defined 0-3 touch reports, with selectable pen
states.
Every touch report includes a “P” (Pen) bit that
indicates the pen state.
Pen Down: P = 1
•Pen Up: P = 0
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A couple of typical setup examples for the TouchMode
are as follows:
Report a pen down P=1 on initial touch, followed
by reporting a stream of pen downs P=1 during
the touch, followed by a final pen up P=0 on touch
release. TouchMode = 0b01010001 = 0x51
Report a pen up P=0 then a pen down P=1 on
initial touch, followed by reporting a stream of pen
downs P=1 during the touch, followed by a final
pen up P=0 on touch release. TouchMode =
0b10110001 = 0xB1
REGISTER 8-1: TouchMode REGISTER FORMAT
R/W R/W R/W R/W R/W R/W R/W R/W
PD2 PD1 PD0 PM1 PM0 PU2 PU1 PU0
bit 7 bit 0
Legend:
R = Readable bit W = Writable bit U = Unimplemented bit, read as ‘0’
bit 7-5 PD<2:0>: Pen-Down State bits (action taken upon pen down).
000 = No touch report
001 = Touch report with P=0
010 = Touch report with P=1
011 = Touch report with P=1, then touch report with P=0
100 = Touch report with P=0, then touch report with P=1, then touch report with P=0
101 = Touch report with P=0, then touch report with P=1
bit 4-3 PM<1:0>: Pen Movement State bits (action taken upon pen movement).
00 = No touch report
01 = Touch report with P=0
10 = Touch report with P=1
bit 2-0 PU<2:0>: Pen-Up State bits (action taken upon pen up).
000 = No touch report
001 = Touch report with P=0
010 = Touch report with P=1
011 = Touch report with P=1, then touch report with P=0
100 = Touch report with P=0, then touch report with P=1, then touch report with P=0
101 = Touch report with P=0, then touch report with P=1
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8.2.11 TouchOptions Register (OFFSET
0x0D)
The TouchOptions register contains various “touch”
related option bits.
8.2.12 CalibrationInset Register (OFFSET
0x0E)
The CalibrationInset register defines the expected
position of the calibration points, inset from the
perimeter of the touch sensor’s active area, by a
percentage of the full scale dimension.
This allows for the calibration targets to be placed inset
from edge to make it easier for a user to touch them.
The CalibrationInset register value is only used when
the CALIBRATION_MODE command is issued to the
controller. In Calibration mode, the controller will
extrapolate the calibration point touch report values by
the defined CalibrationInset percentage to achieve full
scale.
A software application that issues the
CALIBRATION_MODE command must present the
displayed calibration targets at the same inset
percentage as defined in this CalibrationInset register.
Valid values are as follows:
0 CalibrationInset 40
Calibration Inset = (CalibrationInset/2) %, Range of 0-
20% with 0.5% resolution
For example, CalibrationInset = 25 (0x19) yields a
calibration inset of (25/2) or 12.5%. During the
calibration procedure, the controller will internally
extrapolate the calibration point touch values in
Calibration mode by 12.5% to achieve full scale.
FIGURE 8-1: CALIBRATION TARGET
EXAMPLE
REGISTER 8-2: TouchOptions REGISTER
U-0 U-0 U-0 U-0 U-0 U-0 R/W R/W
48W CCE
bit 7 bit 0
Legend:
R = Readable bit W = Writable bit U = Unimplemented bit, read as ‘0’
bit 7-2 Unimplemented: Read as0
bit 1 48W: 4-Wire or 8-Wire Sensor Selection bit
1 = Selects 8-wire Sensor Operating mode
0 = Selects 4-wire Sensor Operating mode
bit 0 CCE: Calibrated Coordinates Enable bit
1 = Enables calibrated coordinates, if the controller has been calibrated
0 = Disables calibrated coordinates
Note: A 4-wire touch sensor will not work if the
48W Configuration bit is incorrectly
defined as 1, which selects 8-wire.
An 8-wire touch sensor will provide basic
operation if the 48W Configuration bit is
incorrectly defined as 0, which selects 4-
wire. However, the benefit of the 8-wire
sensor will only be realized if the 48W
Configuration bit is correctly defined as 1,
selecting 8-wire.
Location of Calibration
Targets presented during
Calibration.
12.5% of
Full Scale
12.5% of
Full Scale
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8.2.13 PenStateReportDelay Register
(OFFSET 0x0F)
The PenStateReportDelay register sets the delay time
between sending of sequential touch reports for the
“Pen-Down” and “Pen-Up” Touch mode states. See
Section 8.2.10 “TouchMode Registe r (offset 0x0C)”
for touch modes.
For example, if “Pen-Up” state of the TouchMode
register is configured to send a touch report with P=1,
followed by a touch report with P=0, then this delay
occurs between the two touch reports. This provides
some timing flexibility between the two touch reports
that may be desired in certain applications. Valid values
are as follows.
0 PenStateReportDelay 255
Pen State Report Delay Time = PenStateReportDelay *
50 μs
8.2.14 TouchReportDelay Register (OFFSET
0x11)
The TouchReportDelay register sets a forced delay
time between successive touch report packets. This
allows slowing down of the touch report rate, if desir-
able for a given application. For example, a given appli-
cation may not need a high rate of touch reports and
may want to reduce the overhead used to service all of
the touch reports being sent. In this situation, increas-
ing the value of this register will reduce the rate at
which the controller sends touch reports. Valid values
are as follows:
0 TouchReportDelay 255
Touch Report Delay Time TouchReportDelay * 500 μs
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9.0 COMMANDS
9.1 Sending Commands
9.1.1 COMMAND SEND FORMAT
The controller supports application-specific
configuration commands as shown in Tab le 9-1 , below.
To ensure command communication is not interrupted
by touch activity, it is recommended that the controller
touch is disabled, prior to other commands. This can be
done as follows:
1. Send DISABLE_TOUCH command
2. Wait 50 ms
3. Send desired commands
4. Send ENABLE_TOUCH command
9.1.2 COMMAND RESPONSE
A received command will be responded to as seen in
Table 9-2 below.
The “Status” value within the response packet should
be one of the following (See Table 9-3):
TABLE 9-1: COMMAND SEND FORMAT
Byte # Name Value Description
1 Header 0x55 Header (mark beginning of command packet)
2 Size 0x<> Size, # of bytes following this byte
3 Command 0x<> Command ID
4 Data 0x<> Data, if applicable for the command
: Data 0x<> Data, if applicable for the command
TABLE 9-2: COMMAND RESPONSE FORMAT
Byte # Name Value Description
1 Header 0x55 Header (mark beginning of command packet)
2 Size 0x<> Size, # of bytes following this byte
3 Status 0x<> Status
4 Command 0x<> Command ID
5 Data 0x<> Data, if applicable for the command
: Data 0x<> Data, if applicable for the command
TABLE 9-3: COMMAND RESPONSE
STATUS VALUES
S t atus Value Descript ion
0x00 Success
0x01 Command Unrecognized
0x03 Header Unrecognized
0x04 Command Time Out (exceeded ~100
ms)
0xFC Cancel Calibration mode
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AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
9.1.3 DISABLE TOUCH BEFORE
SENDING SUBSEQUENT
COMMANDS
The AR1000 does not support full duplex
communications. It cannot send touch reports to the
host simultaneously with receiving commands from the
host.
Disable AR1000 touch reporting prior to sending any
other command(s), then re-enable touch reporting
when complete with executing other commands.
1. Send the DISABLE_TOUCH command.
Check for expected command response.
2. Send a desired command.
Check for expected command response.
3. Repeat at step 2 if another command is to be
sent.
4. Send the ENABLE_TOUCH command.
Check for expected command response.
9.1.4 CONFIRM COMMAND IS SENT
Confirm each command sent to the AR1000, prior to
issuing another command, to ensure it is executed.
This is accomplished by evaluating the AR1000
response to a command that has been sent to it.
Check for each of the following five conditions to be
met (See Tab le 9- 4).
0x<> represents a value that is dependent on the
command.
An error has occurred if no response is received at all
or if any of the above conditions are not met in the
response from the AR1000. If an error condition
occurs, delay for a period of ~50 ms then send the
same command again.
TABLE 9-4: COMMAND RESPONSE ERROR CONDITIONS
Condition Response Byte Description
Header 1 Header 0x55 value is expected
Size 2 Size 0x<> value to match what is expected for command sent
Status 3 Status 0x00 “success” value is expected
ID 4 Command ID 0x<> value to match what is expected (ID of sent command)
Data 5 to end Data byte count to match what is expected for command sent
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9.2 AR1000 Commands
9.3 AR1000 Command Descriptions
9.3.1 GET_VERSION – 0x10
Controller will return version number and type.
Send: <0x55><0x01><0x10>
Receive: <0x55><0x05><Response><0x10><Ver-
sion High><Version Low><Type>
where <Type>
TABLE 9-5: COMMAND SET SUMMARY
Command
Value Co mma nd Desc ript ion
0x10 GET_VERSION
0x12 ENABLE_TOUCH
0x13 DISABLE_TOUCH
0x14 CALIBRATE_MODE
0x20 REGISTER_READ
0x21 REGISTER_WRITE
0x22 REGISTER_START_ADDRESS_REQUEST
0x23 REGISTERS_WRITE_TO_EEPROM
0x28 EEPROM_READ
0x29 EEPROM_WRITE
0x2B EEPROM_WRITE_TO_REGISTERS
REGISTER 9-1: GET_VERSION <TYPE> FORMAT
R/W R/W R/W R/W R/W R/W R/W R/W
RS1 RS0 TP5 TP4 TP3 TP2 TP1 TP0
bit 7 bit 0
Legend:
R = Readable bit W = Writable bit U = Unimplemented bit, read as ‘0’
bit 7-6 RS<1:0>: Resolution of Touch Coordinates bits
00 = 8-bit
01 = 10-bit
10 = 12-bit
bit 5-0 TP<5:0>: Type of Controller bits
001010 = ARA10
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AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
9.3.2 ENABLE_TOUCH – 0x12
Controller will send touch coordinate reports for valid
touch conditions.
Send: <0x55><0x01><0x12>
Receive: <0x55><0x02><Response><0x12>
9.3.3 DISABLE_TOUCH – 0x13
Controller will not send any touch coordinate reports. A
touch will, however, still wake-up the controller if
asleep.
Send: <0x55><0x01><0x13>
Receive: <0x55><0x02><Response><0x13>
9.3.4 CALIBRATE – 0x14
Enter Calibration mode. This instructs the controller to
enter a mode of accepting the next four touches as the
calibration point coordinates. See Section 10.1 “Cali-
bration of Touch Sensor with Controller” for an
example.
Completion of Calibration mode will automatically store
the calibration point coordinates in on-board controller
memory and set (to 1) the CCE bit of the TouchOptions
register. This bit enables the controller to report touch
coordinates that have been processed with the
previously collected calibration data.
To provide for proper touch orientation, the four
sequential calibration touches must be input in the
physical order on the touch sensor, as shown in
Figure 9-1.
FIGURE 9-1: CALIBRATION ROUTINE
SEQUENCE
Upon completion, the controller’s register values and
calibration data are stored to the EEPROM.
The Calibration mode will be canceled by sending any
command before the mode has been completed. If the
calibration is canceled, the controller response may
appear incorrect or incomplete. This is expected
behavior.
Touch Sensor
#1 #2
#4 #3
Upper Lef t Upper Right
Lower RightLower Left
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 34 2009-2016 Microchip Technology Inc.
9.3.4.1 AR1010/AR1020 Calibrate
Response
A successful CALIBRATE command results in five
response packets being sent to the host.
Once the response has been received for the
completed 4th target, a delay of one second must be
implemented prior to sending any commands to the
controller. This one second delay insures all data has
been completely written to the EEPROM.
9.3.4.2 AR1011/AR1021 Calibrate
Response
A successful CALIBRATE command results in six
response packets being sent to the host.
Send: <0x55><0x02><0x14><Calibration Type>
Calibration Type Description
0x04 4 point
Receive: <0x55><0x02><0x00><0x14> for initial command response
<0x55><0x02><0x00><0x14> Response for touch of Calibration point #1
<0x55><0x02><0x00><0x14> Response for touch of Calibration point #2
<0x55><0x02><0x00><0x14> Response for touch of Calibration point #3
<0x55><0x02><0x00><0x14> Response for touch of Calibration point #4
Send: <0x55><0x02><0x14><Calibration Type>
Calibration Type Description
0x04 4 point
Receive: <0x55><0x02><0x00><0x14> for initial command response
<0x55><0x02><0x00><0x14> Response for touch of Calibration point #1
<0x55><0x02><0x00><0x14> Response for touch of Calibration point #2
<0x55><0x02><0x00><0x14> Response for touch of Calibration point #3
<0x55><0x02><0x00><0x14> Response for touch of Calibration point #4
<0x55><0x02><0x00><0x14> Response after EEPROM has been written
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AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
9.3.4.3 Calibration Data Encoded and
Stored in EEPROM
System integrators may prefer to preload a calibration
into their design. This allows the user to properly
navigate to the calibration routine icon or shortcut
without the use of a mouse. This also addresses the
need to calibrate each system individually before
deploying it to the field.
The raw touch coordinates, decoded by the controller,
for each of the four calibration touches are extrapolated
if CalibrationInset was non-zero. The four coordinate
pairs are then re-oriented, if required, such that the
upper left corner is the minimum (X,Y) “origin” value
pair and the lower right corner is the maximum (X,Y)
value pair.
Coordinates are 10-bit significant values, scaled to
16-bit and stored in a High (Hi) and Low (Lo) byte pair.
Decode the above data to as follows:
1. Swap the order of stored low and high bytes for
a given coordinate.
2. Convert the 16-bit value (stored high and low
bytes) from hexadecimal to decimal.
3. Divide the result by 64 to properly rescale the
16-bit stored value back to a 10-bit significant
coordinate.
Example of Low = 0x40 and High = 0xF3:
Swap: 0xF340
Hex to Decimal: 62272
Divide by 64: 973
For storing desired calibration values to the EEPROM:
AR1010/AR1020 (See Sec tion 9.3.12 “EEPROM
Map”).
AR1011/AR1021 (See Section 9.3.12 “EEPROM
Map” and Secti on 10.2 “AR1011/AR1021 Stor -
ing Default Calibration Values to EEPROM”).
Separator Upper Left (Node 1) Upper Right (Node 2) Lower Right (Node 3) Lower Left (Node 4) Flip State
XY X YX Y X Y
Lo Hi Lo Hi Lo Hi Lo Hi Lo Hi Lo Hi Lo Hi Lo Hi
REGISTER 9-2: FLIP STATE BYTE
U-0 U-0 U-0 U-0 U-0 R/W R/W R/W
XYFLIP XFLIP YFLIP
bit 7 bit 0
Legend:
R = Readable bit W = Writable bit U = Unimplemented bit, read as ‘0’
bit 7-3 Unimplemented: Read as0
bit 2 XYFLIP: X and Y Axis Flip bit
1 = X and Y axis are flipped
0 = X an Y axis are not flipped
bit 1 XFLIP: X-Axis Flip bit
1 = X-axis flipped
0 = X-axis not flipped
bit 0 YFLIP:Y-Axis Flip bit
1 = Y-axis flipped
0 = Y-axis not flipped
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
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9.3.5 REGISTER_READ – 0x20
Reads a value from a controller register location. This
can be used to determine a controller configuration
setting.
Configuration registers are defined as an Offset value
from the Start address for the register group. Read a
register as follows:
1.
Issue the
REGISTER_START_ADDRESS_REQUEST
command to obtain the Start address for the
register group
.
2. Calculate the desired register’s absolute
address by adding the register’s Offset value to
Start address for the register group.
3. Issue this
REGISTER_READ
command, as
follows, using the calculated register’s absolute
address:
Send: <0x55><0x04><0x20><Register Address
High byte><Register Address Low
byte><# of Registers to Read>
Register Address High byte: 0x00
# of Registers to Read: 0x01 thru 0x08
Receive: <0x55><0x02 + # of Registers
Read><Response><0x20><Register
value>…<Register value>
The AR1000 controller will ignore the value entered for
the Register Address High Byte. However, 0x00 is
recommended to safeguard against any possible future
product development.
9.3.6 REGISTER_WRITE – 0x21
Write a value to a controller register location. This can
be used to change a controller configuration setting.
Configuration registers are defined as an Offset value
from the Start address for the register group. Write a
register as follows:
1.
Issue the
REGISTER_START_ADDRESS_REQUEST
command to obtain the Start address for the
register group.
2. Calculate the desired register’s absolute
address by adding the register’s Offset value to
Start address for the register group.
3. Issue this REGISTER_WRITE command, as
follows, using the calculated register’s absolute
address:
Send: <0x55><0x04 + # Registers to
Write><0x21><Register Address High
byte><Register Address Low byte>
<# of Registers to
Write><Data>…<Data>
Register Address High byte: 0x00
# of Registers to Read: 0x01 thru 0x08
Receive: <0x55><0x02><Response><0x21>
The AR1000 controller will ignore the value entered for
the Register Address High Byte. However, 0x00 is
recommended to safeguard against any possible future
product development.
9.3.7
REGISTER_START_ADDRESS_REQUEST
– 0x22
Configuration registers are defined as an Offset value
from the Start address for the register group. This
command returns the Start address for the register
group.
Send: <0x55><0x01><0x22>
Receive: <0x55><0x03><Response><0x22><Regi
ster Start Address>
9.3.8 REGISTERS_WRITE_TO_EEPROM
0x23
Save Configuration register values to EEPROM. This
allows the controller to remember configurations
settings through controller power cycles.
Send: <0x55><0x01><0x23>
Receive: <0x55><0x02><Response><0x23>
9.3.9 EEPROM_READ – 0X28
The controller has 256 bytes of on-board EEPROM.
The first 128 bytes (address range 0x00-0x7F)
are reserved by the controller for the
Configuration register settings and calibration
data.
The second 128 bytes (address range
0x80-0xFF) are provided for the user’s
application, if desired.
This command provides a means to read values from
the EEPROM.
Send: <0x55><0x04><0x28><EEPROM Address
High byte><EEPROM Address Low
byte><# of EEPROM to Read>
Register Address High byte: 0x00
# of Registers to Read: 0x01 thru 0x08
Receive: <0x55><0x02 + # EEPROM
Read><Response><0x28><EEPROM
value>…<EEPROM value>
The AR1000 controller will ignore the value entered for
the EEPROM Address High Byte. However, 0x00 is
recommended to safeguard against any possible future
product development.
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AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
9.3.10 EEPROM_WRITE – 0x29
The controller has 256 bytes of on-board EEPROM.
This command provides a means to write values to the
user space within the EEPROM.
The first 128 bytes (address range 0x00-0x7F)
are reserved by the controller for the Configura-
tion register settings and calibration data. Only the
Register Write to EEPROM command should be
used to write Configuration registers to EEPROM.
Failure to use the Register Write command to
save Configuration registers to EEPROM may
result in failures or reverting to previously stored
Configuration register values.
The second 128 bytes (address range
0x80-0xFF) are provided for the user’s
application, if desired.
Write to EEPROM as follows:
Send: <0x55><0x04 + # EEPROM to
Write><0x29><EEPROM Address High
byte><EEPROM Address Low byte>
<# of EEPROM to
Write><Data>…<Data>
Register Address High byte: 0x00
# of Registers to Read: 0x01 thru 0x08
Receive: <0x55><0x02><Response><0x29>
The AR1000 controller will ignore the value entered for
the EEPROM Address High Byte. However, 0x00 is
recommended to safeguard against any possible future
product development.
9.3.11 EEPROM_WRITE_TO_REGISTERS
0x2B
Write applicable EEPROM data to Configuration regis-
ters. This will cause the controller to immediately begin
using changes made to EEPROM stored Configuration
register values. A power cycle of the controller will
automatically cause the controller to use changes
made to the EEPROM stored Configuration register
values, without the need for issuing this command. This
command eliminates the need for the power cycle.
Send: <0x55><0x01><0x2B>
Receive: <0x55><0x02><Response><0x2B>
9.3.12 EEPROM MAP
The first 128 bytes in address range 0x00:0x7F are
reserved by the controller for the Configuration register
settings and calibration data. The mapping of data in
this reserved controller space of the EEPROM may
change over different revisions within the product
lifetime.
The EEPROM_WRITE command must not be used to
write directly to the lower 128 bytes of the controller
EEPROM space of 0x00:0x7F.
The second 128 bytes in address range 0x80:0xFF are
provided for the user’s application, if desired.
Warning: ONLY write to user EEPROM addresses of
0x80-0xFF.
One of the following actions is required for
EEPROM changes to be used by the
controller:
• The controller power must be cycled
from OFF to ON or
• Issue the EEPROM_WRITE_TO_REG-
ISTERS command.
TABLE 9-6: AR1010/AR1020 EEPROM
AND REGISTER MAP
EEPROM Address Function
0x00 <Special Use>
0x01 <Special Use>
0x02 <Special Use>
0x03 Touch Threshold
0x04 Sensitivity Filter
0x05 Sampling Fast
0x06 Sampling Slow
0x07 Accuracy Filter Fast
0x08 Accuracy Filter Slow
0x09 Speed Threshold
0x0A <Special Use>
0x0B Sleep Delay
0x0C Pen-Up Delay
0x0D Touch Mode
0x0E Touch Options
0x0F Calibration Inset
0x10 Pen State Report Delay
0x11 <Reserved>
0x12 Touch Report Delay
0x13 <Special Use>
0x14 Data Block Separator
0x15 Calibration UL X-low
0x16 Calibration UL X-high
0x17 Calibration UL Y-low
0x18 Calibration UL Y-high
0x19 Calibration UR X-low
0x1A Calibration UR X-high
0x1B Calibration UR Y-low
0x1C Calibration UR Y-high
0x1D Calibration LR X-low
0x1E Calibration LR X-high
0x1F Calibration LR Y-low
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DS40001393C-page 38 2009-2016 Microchip Technology Inc.
0x20 Calibration LR Y-high
0x21 Calibration LL X-low
0x22 Calibration LL X-high
0x23 Calibration LL Y-low
0x24 Calibration LL Y-high
0x25 Calibration Flip State
0x26:0x7E <Special Use>
0x7F End of Controller Space
0x80:0xFF User Space
TABLE 9-7: AR1011/AR1021 EEPROM
AND REGISTER MAP
EEPROM Address Function
0x00 Not used
0x01 Configuration Registers –
Block Key
0x02 <Special Use>
0x03 <Special Use>
0x04 Touch Threshold
0x05 Sensitivity Filter
0x06 Sampling Fast
0x07 Sampling Slow
0x08 Accuracy Filter Fast
0x09 Accuracy Filter Slow
0x0A Speed Threshold
0x0B <Special Use>
0x0C Sleep Delay
0x0D Pen-Up Delay
0x0E Touch Mode
0x0F Touch Options
0x10 Calibration Inset
0x11 Pen State Report Delay
0x12 <Special Use>
0x13 Touch Report Delay
0x14 <Special Use>
0x15 Configuration Registers –
Checksum
0x16 Calibration - Block Key
0x17 Calibration UL X-low
0x18 Calibration UL X-high
0x19 Calibration UL Y-low
0x1A Calibration UL Y-high
0x1B Calibration UR X-low
0x1C Calibration UR X-high
TABLE 9-6: AR1010/AR1020 EEPROM
AND REGISTER MAP
EEPROM Address Function
0x1D Calibration UR Y-low
0x1E Calibration UR Y-high
0x1F Calibration LR X-low
0x20 Calibration LR X-high
0x21 Calibration LR Y-low
0x22 Calibration LR Y-high
0x23 Calibration LL X-low
0x24 Calibration LL X-high
0x25 Calibration LL Y-low
0x26 Calibration LL Y-high
0x27 Calibration Flip State
0x28 Calibration – Checksum
0x29:0x50 <Special Use>
0x51:0x7F <Reserved>
0x80:0xFF User Space
TABLE 9-7: AR1011/AR1021 EEPROM
AND REGISTER MAP
EEPROM Address Function
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AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
10.0 APPLICATION NOTES
10.1 Calibration of Touch Sensor with
Controller
The reported coordinates from a touch screen
controller are typically calibrated to the application’s
video display. The task is often left up to the host to
perform. This controller provides a feature for it to send
coordinates that have already been calibrated, rather
than the host needing to perform this task. If enabled,
the feature will apply pre-collected 4-point calibration
data to the reported touch coordinates. Calibration only
accounts for X and Y directional scaling. It does not
correct for angular errors due to rotation of the touch
sensor on the video display.
The calibration process can be canceled at anytime by
sending a command to the controller.
Upon completion of the calibration process, the
calibration data is automatically stored to the EEPROM
and “Calibrated Coordinates” is enabled.
The process of “calibration” with the controller is
described below.
1. Disable touch reporting by issuing <Disable
Touch> command.
Send: <0x55><0x01><0x13>
Receive: <0x55><0x02><Response><0x13>
2. Get register group Start address by issuing
REGISTER_START_ADDRESS_REQUEST
command.
A register Start address of 0x20 is used below, for
this example.
Send: <0x55><0x01><0x22>
Receive: <0x55><0x03><0x00><0x22><0x20>
3. Calculate the CalibrationInset register’s address
by adding its offset value of 0x0E to the register
group Start address of 0x20.
Register Address = Register Start Address +
CalibratioInset Register Offset = 0x20 + 0x0E = 0x2E
4. Calculate the desired value for the
CalibrationInset register.
A Calibration Inset of 12.5% is used below for this
example.
CalibrationInset = 2 * Desire Calibration Inset % = 2 *
12.5 = 25 = 0x19
5. Set the Calibration Inset by writing the desired
value to the CalibrationInset register.
Send:<0x55><0x05><0x21><0x00><0x2E><0x01
><0x19>
Receive: <0x55><0x02><0x00><0x21>
6. Issue the CALIBRATE_MODE command.
Send: <0x55><0x02><0x14><0x04>
Receive: <0x55><0x02><0x00><0x14>
7. Software must display the first calibration point
target in the upper left quadrant of the display
and prompt the user to touch and release the
target.
FIGURE 10-1: SUGGESTED TEXT FOR
FIRST CALIBRATION
TARGET
8. Wait for the user to touch and release the first
calibration point target. Do this by looking for a
controller response of:
<0x55><0x02><0x00> <0x14>
9. Software must display the second calibration
point target in the upper right quadrant of the
display and prompt the user to touch and
release the target.
FIGURE 10-2: SUGGESTED TEXT FOR
SECOND CALIBRATION
TARGET
10. Wait for the user to touch and release the
second calibration point target. Do this by
looking for a controller response of:
<0x55><0x02><0x00><0x14>
Touch and
Release Target
Touch and
Release Target
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 40 2009-2016 Microchip Technology Inc.
11. Software must display the third calibration point
target in the lower right quadrant of the display
and prompt the user to touch and release the
target.
FIGURE 10-3: SUGGESTED TEXT FOR
THIRD CALIBRATION
TARGET
12. Wait for the user to touch and release the third
calibration point target. Do this by looking for a
controller response of:
<0x55><0x02><0x00><0x14>
13. Software must display the fourth calibration
point target in the lower left quadrant of the
display and prompt the user to touch and
release the target.
FIGURE 10-4: SUGGESTED TEXT FOR
FOURTH CALIBRATION
TARGET
14. Wait for the user to touch and release the fourth
calibration point target. Do this by looking for a
controller response of:
<0x55><0x02><0x00><0x14>
15. Wait for the controller to correctly write
calibration data into EEPROM
• AR1010/AR1020: Wait one second for data to
be stored into EEPROM
• AR1011/AR1021: Wait for a controller
response of <0x55><0x02><0x00><0x14>
16. Enable touch reporting by issuing
ENABLE_TOUCH command.
Send: <0x55><0x01><0x12>
Receive: <0x55><0x02><Response><0x12>
Touch and
Release Target
Touch and
Release Target
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AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
10.2 AR1011/AR1021 Storing Default
Calibration Values to EEPROM
If you wish to implement fixed calibration values,
preloaded into the AR1000 EEPROM, then the
following procedure must be followed (See
Section 10.2.1 “Preparation for Fixed Calibration
Values).
10.2.1 PREPARATION FOR FIXED
CALIBRATION VALUES
Determine if fixed calibration values are suitable for
your application and determine your desired values.
Calculate a checksum for your custom data set. See
Section 9.3.4.3 “Calibration Data Encoded and
Stored in EEPROM” for additional details regarding
calibration data format.
An example of calculating the checksum is shown
below (See Tab le 1 0-1 ).
The Checksum is an 8-bit value calculated by
successive additions with overflow ignored, as shown
below.
Checksum = 0x45
For each of the 18 calibration values, starting at the
Block Key and ending with the Flip State
Checksum += Calibration value
Next Calibration value
TABLE 10-1: CHECKSUM CALCULATION EXAMPLE
Description Value Operation Checksum Result
Seed 0x45 n/a 0x45
Block Key 0x55 0x45 + 0x55 = 0x9A
Upper Left X Low byte 0x06 0x9A + 0x06 = 0xA0
Upper Left X High byte 0x1B 0xA0 + 0x1B = 0xBB
Upper Left Y Low byte 0xA5 0xBB + 0xA5 = 0x60
Upper Left Y High byte 0x08 0x60 + 0x08 = 0x68
Upper Right X Low byte 0x13 0x68 + 0x13 = 0x7B
Upper Right X High byte 0xDF 0x7B + 0xDF = 0x5A
Upper Right Y Low byte 0xF4 0x5A + 0xF4 = 0x4E
Upper Right Y High byte 0x0B 0x4E + 0x0B = 0x59
Lower Right X Low byte 0x98 0x59 + 0x98 = 0xF1
Lower Right X High byte 0xE4 0xF1 + 0xE4 = 0xD5
Lower Right Y Low byte 0x1E 0xD5 + 0x1E = 0xF3
Lower Right Y High byte 0xEC 0xF3 + 0xEC = 0xDF
Lower Left X Low byte 0xBF 0xDF + 0xBF = 0x9E
Lower Left X High byte 0x1A 0x9E + 0x1A = 0xB8
Lower Left Y Low byte 0x32 0xB8 + 0x32 = 0xEA
Lower Left Y High byte 0xE7 0xEA + 0xE7 = 0xD1
Flip State 0x01 0xD1 + 0x01 = 0xD2
Checksum 0xD2
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DS40001393C-page 42 2009-2016 Microchip Technology Inc.
10.2.2 EXECUTION OF FIXED
CALIBRATION VALUE LOADING
Follow error checking practices by checking the
AR1000 responses to issued commands.
1. Send the AR1000 DISABLE_TOUCH command.
2. Use the AR1000 EEPROM_WRITE command
multiple times to write the following to the
AR1000 EEPROM.
a. Block Key 0x55 to address 0x16
b. Data set to addresses 0x17:0x27. See
Section 9.3.4.3 “Calibration Data
Encoded and Stored in EEPROM and
Section 9.3.12 “EEPROM Map”.
c. Checksum for the data block to address
0x28
d. Mirror image of a, b and c from above to
address 0x3E:0x50
3. Set the CCE bit of the TouchOptions register.
This will enable the controller to use the
calibration data on the next power boot. See
Section 10.2.3 “Configuring the CCE bit to
Use Fixed Calibration Values” for additional
details on the CCE bit.
4. Send the AR1000 ENABLE_TOUCH (0x12)
command.
10.2.3 CONFIGURING THE CCE BIT TO
USE FIXED CALIBRATION VALUES
The CCE bit of the TouchOptions Register (offset
0x0D) must be set to ‘1’ to enable the usage of the
stored calibration values in EEPROM.
This should be completed before re-enabling the
controller via the ENABLE_TOUCH command.
REGISTER 10-1: CCE BIT FORMAT
U-0 U-0 U-0 U-0 U-0 U-0 R/W R/W
48W CCE
bit 7 bit 0
Legend:
R = Readable bit W = Writable bit U = Unimplemented bit, read as ‘0’
bit 7-2 Unimplemented: Read as0
bit 1 48W: 4-Wire or 8-Wire Sensor Selection bit
1 = Selects 8-wire Sensor Operating mode
0 = Selects 4-wire Sensor Operating mode
bit 0 CCE: Calibrated Coordinates Enable bit
1 = Enables calibrated coordinates, if the controller has been calibrated
0 = Disables calibrated coordinates
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AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
1. Send the DISABLE_TOUCH (0x13) command.
2. Send the
REGISTER_START_ADDRESS_REQUEST
(0x22) to determine the absolute address for
TouchOptions Register.
3. Send the REGISTER_WRITE (0x21) command
to set the CCE bit of the TouchOptions Register.
4. Send REGISTERS_WRITE_TO_EEPROM (0x23)
command to have all current registers stored
into EEPROM.
5. Send the AR1000 ENABLE_TOUCH (0x12)
command.
The controller will use the stored calibration data after
cycling power to the controller.
10.2.4 EEPROM_WRITE COMMAND TO
STORE DEFAULT CALIBRATION
The EEPROM_WRITE command is shown in this
section. See Section 9.0 “Commands” for more
command details.
10.2.5 QUALITY TEST
Although not required, a level of quality assurance can
be added to the process by the application issuing
multiple EEPROM_READ commands to the AR1000.
The response data from the EEPROM_READ commands
would be tested by the application against the
application’s desired data as a quality check.
10.2.6 EXAMPLE COMMAND SEQUENCE
An example eight command sequence for the entire
process is shown below.
All values shown are in hexadecimal.
Calibration values are applications specific and have
been symbolically represented as follows:
<> = application specific value
Send to AR1000:
0x55 Header
0x<> Number of bytes to follow this one
0x29 Command ID
0x00 Desired EEPROM address to write high
byte. Always 0x00
0x<> Desired EEPROM address to write low
byte
0x<> Number of consecutive EEPROM
addresses to write (supports 0x01 to 0x08)
0x<> Value # 1 to write
0x<> Value # 2 to write, if applicable
0x<> Value # 3 to write, if applicable
0x<> Value # 4 to write, if applicable
0x<> Value # 5 to write, if applicable
0x<> Value # 6 to write, if applicable
0x<> Value # 7 to write, if applicable
0x<> Value # 8 to write, if applicable
Response from AR1000:
0x55 Header
0x02 Number of bytes to follow this one
0x00 Success response
0x29 Command ID
ULxL = Upper Left corner x-coordinate Low byte
:
LLyH = Lower Left corner y-coordinate High byte
DISABLE_TOUCH
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 44 2009-2016 Microchip Technology Inc.
Disable Touch
Command: 55 01 13
Response: 55 020013
Write Calibration to EEPROM Image # 1
Command: 55 0C 29 00 16 08 55 ULxL ULxH ULyL ULyH URxL URxH URyL
Response: 55 020029
Command: 55 0C 29 00 1E 08 URyH LRxL LRxH LRyL LRyH LLxL LLxH LLyL
Response: 55 020029
Command: 55 07 29 00 26 03 LLyH FlipS Chksm
Response: 55 020029
Write Calibration to EEPROM Image # 2
Command: 55 0C 29 00 3E 08 55 ULxL ULxH ULyL ULyH URxL URxH URyL
Response: 55 020029
Command: 55 0C 29 00 46 08 URyH LRxL LRxH LRyL LRyH LLxL LLxH LLyL
Response: 55 020029
Command: 55 07 29 00 4E 03 LLyH FlipS Chksm
Response: 55 020029
Enable Use of Calibrated Data
Command: 55 01 22
Response: 55 030022<Start Address>
Command:
4/8-Wire 55 05 21 00 <Start Address + 0x0D> 01 01
5-Wire 55 05 21 00 <Start Address + 0x0D> 01 03
Response: 55 020021
Enable Touch
Command: 55 01 12
Response: 55 020012
2009-2016 Microchip Technology Inc. DS40001393C-page 45
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
11.0 EL ECTRICAL SPECIFICATIONS
Absolute Maximum Ratings(†)
Ambient temperature under bias....................................................................................................... -40°C to +125°C
Storage temperature ........................................................................................................................ -65°C to +150°C
Voltage on VDD with respect to VSS .................................................................................................... -0.3V to +6.5V
Voltage on all other pins with respect to VSS ........................................................................... -0.3V to (VDD + 0.3V)
Total power dissipation................................................................................................................................... 800 mW
Maximum current out of VSS pin .................................................................................................................... 300 mA
Maximum current into VDD pin ....................................................................................................................... 250 mA
Input clamp current (VI < 0 or VI > VDD)20 mA
Maximum output current sunk by any I/O pin.................................................................................................... 25 mA
Maximum output current sourced by any I/O pin .............................................................................................. 25 mA
† NOTICE: 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 those or any other conditions above those
indicated in the operation listings of this specification is not implied. Exposure to maximum rating conditions for
extended periods may affect device reliability.
† NOTICE: This device is sensitive to ESD damage and must be handled appropriately. Failure to properly handle
and protect the device in an application may cause partial to complete failure of the device.
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 46 2009-2016 Microchip Technology Inc.
11.1 Minimum Operating Voltage
The AR1000 series controller will operate down to 2.5V ± 5%. Touch performance will be optimized by using the
highest allowable voltage for the design.
The PICkit™ Serial included in the AR1000 Development kit supports 3V-5V range of operation.
11.2 AR1000 Electrical Characteristics
Operating Voltage: 2.5 VDD 5.25V
Function Pin Input Output
M1 M1 VSS VIL 0.15*VDD
(0.25*VDD + 0.9V) VIH VDD
M2 M2 VSS VIL 0.15*VDD
(0.25*VDD + 0.9V) VIH VDD
SCL/SCK SCL/SCK/TX VSS VIL 0.2*VDD
0.8*VDD VIH VDD
TX SCL/SCK/TX VSS VOL(1) (1.2V – 0.15*VDD)(2)
(1.25*VDD – 2.25V)(3) VOH(1) VDD
SDI SDI/SDA/RX VSS VIL 0.2*VDD
0.8*VDD VIH VDD
SDO SDO VSS VOL(1) (1.2V – 0.15*VDD)(2)
(1.25*VDD – 2.25V)(3) VOH(1) VDD
SIQ SIQ VSS VOL(1) (1.2V – 0.15*VDD)(2)
(1.25*VDD – 2.25V)(3) VOH(1) VDD
SDA SDI/SDA/RX VSS VIL 0.2*VDD
0.8*VDD VIH VDD
Open-drain
RX SDI/SDA/RX VSS VIL 0.2*VDD
0.8*VDD VIH VDD
SS SS VSS VIL 0.2*VDD
0.8*VDD VIH VDD
Note 1: These parameters are characterized but not tested.
2: At 10 mA.
3: At -4 mA.
2009-2016 Microchip Technology Inc. DS40001393C-page 47
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
12.0 PACKAGING INFORMATION
12.1 Package Marking Inf ormation
*Standard PICmicro® device marking consists of Microchip part number, year code, week code and
traceability code. For PICmicro device marking beyond this, certain price adders apply. Please check
with your Microchip Sales Office. For QTP devices, any special marking adders are included in QTP
price.
Legend: XX...X Customer-specific information
Y Year code (last digit of calendar year)
YY Year code (last 2 digits of calendar year)
WW Week code (week of January 1 is week ‘01’)
NNN Alphanumeric traceability code
Pb-free JEDEC designator for Matte Tin (Sn)
*This package is Pb-free. The Pb-free JEDEC® designator ( )
can be found on the outer packaging for this package.
Note: In the event the full Microchip part number cannot be marked on one line, it will
be carried over to the next line, thus limiting the number of available
characters for customer-specific information.
3
e
3
e
20-Lead SSOP (5.30 mm) Example
20-Lead SOIC (7.50 mm) Example
XXXXXXXXXXXX
YYWWNNN
XXXXXXXXXXXX
XXXXXXXXXXXX
AR1021
I/SS
AR1021
I/SO
3
e
3
e
1042256
1042256
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 48 2009-2016 Microchip Technology Inc.
12.2 Package Marking Info rmation (Continued)
*Standard PICmicro® device marking consists of Microchip part number, year code, week code and
traceability code. For PICmicro device marking beyond this, certain price adders apply. Please check
with your Microchip Sales Office. For QTP devices, any special marking adders are included in QTP
price.
Legend: XX...X Customer-specific information
Y Year code (last digit of calendar year)
YY Year code (last 2 digits of calendar year)
WW Week code (week of January 1 is week ‘01’)
NNN Alphanumeric traceability code
Pb-free JEDEC designator for Matte Tin (Sn)
*This package is Pb-free. The Pb-free JEDEC® designator ( )
can be found on the outer packaging for this package.
Note: In the event the full Microchip part number cannot be marked on one line, it will
be carried over to the next line, thus limiting the number of available
characters for customer-specific information.
3
e
3
e
20-Lead QFN (4x4x0.9 mm) Example
PIN 1 PIN 1
I/ML
3
e
1042256
AR1021
2009-2016 Microchip Technology Inc. DS40001393C-page 49
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
12.3 Ordering
Note: The AR1011/AR1021 are recommended
for new designs. The AR1010/AR1020 are
still supported and available, but are not
recommended for new designs.
TABLE 12-1: ORDERING PART NUMBERS
Part Number Communication
Type Temp. Range Pin Package Packing
AR1011-I/ML UART -40°C to + 85°C QFN, 20 pin Tube
AR1011-I/SO UART -40°C to + 85°C SOIC, 20 pin Tube
AR1011-I/SS UART -40°C to + 85°C SSOP, 20 pin Tube
AR1011T-I/ML UART -40°C to + 85°C QFN, 20 pin T/R
AR1011T-I/SO UART -40°C to + 85°C SOIC, 20 pin T/R
AR1011T-I/SS UART -40°C to + 85°C SSOP, 20 pin T/R
AR1021-I/ML I2C/SPI -40°C to + 85°C QFN, 20 pin Tube
AR1021-I/SO I2C/SPI -40°C to + 85°C SOIC, 20 pin Tube
AR1021-I/SS I2C/SPI -40°C to + 85°C SSOP, 20 pin Tube
AR1021T-I/ML I2C/SPI -40°C to + 85°C QFN, 20 pin T/R
AR1021T-I/SO I2C/SPI -40°C to + 85°C SOIC, 20 pin T/R
AR1021T-I/SS I2C/SPI -40°C to + 85°C SSOP, 20 pin T/R
AR1010-I/ML UART -40°C to + 85°C QFN, 20 pin Tube
AR1010-I/SO UART -40°C to + 85°C SOIC, 20 pin Tube
AR1010-I/SS UART -40°C to + 85°C SSOP, 20 pin Tube
AR1010T-I/ML UART -40°C to + 85°C QFN, 20 pin T/R
AR1010T-I/SO UART -40°C to + 85°C SOIC, 20 pin T/R
AR1010T-I/SS UART -40°C to + 85°C SSOP, 20 pin T/R
AR1020-I/ML I2C/SPI -40°C to + 85°C QFN, 20 pin Tube
AR1020-I/SO I2C/SPI -40°C to + 85°C SOIC, 20 pin Tube
AR1020-I/SS I2C/SPI -40°C to + 85°C SSOP, 20 pin Tube
AR1020T-I/ML I2C/SPI -40°C to + 85°C QFN, 20 pin T/R
AR1020T-I/SO I2C/SPI -40°C to + 85°C SOIC, 20 pin T/R
AR1020T-I/SS I2C/SPI -40°C to + 85°C SSOP, 20 pin T/R
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 50 2009-2016 Microchip Technology Inc.
12.4 Package Details
The following sections give the technical details of the packages.
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2009-2016 Microchip Technology Inc. DS40001393C-page 51
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
RECOMMENDED LAND PATTERN
Microchip Technology Drawing No. C04-2072B
20-Lead Plastic Shrink Small Outline (SS) - 5.30 mm Body [SSOP]
For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging
Note:
c
G
E
X1
Y1
SILK SCREEN
Dimension Limits
Units
CContact Pad Spacing
Contact Pitch
MILLIMETERS
0.65 BSC
MIN
E
MAX
7.20
Contact Pad Length (X20)
Contact Pad Width (X20)
Y1
X1
1.75
0.45
BSC: Basic Dimension. Theoretically exact value shown without tolerances.
Notes:
1. Dimensioning and tolerancing per ASME Y14.5M
GDistance Between Pads 0.20
NOM
0.45
0.65
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 52 2009-2016 Microchip Technology Inc.
Note: For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging
Note: For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging
2009-2016 Microchip Technology Inc. DS40001393C-page 53
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
Note: For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging
Note: For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 54 2009-2016 Microchip Technology Inc.
Note: For the most current package drawings, please see the Microchip Packaging Specification located at
http://www.microchip.com/packaging
2009-2016 Microchip Technology Inc. DS40001393C-page 55
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
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D
EXPOSED
PAD
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TOP VIEW NOTE 1
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AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 56 2009-2016 Microchip Technology Inc.
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2009-2016 Microchip Technology Inc. DS40001393C-page 57
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
APPENDIX A: DATA SHEET
REVISION HISTORY
Revision A (07/2009)
Original release of this data sheet.
Revision B (03/2012)
Updated data sheet.
Revision C (07/2016)
Updated Table 4-1 and Tabl e 5- 1. Other minor
corrections.
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
DS40001393C-page 58 2009-2016 Microchip Technology Inc.
APPENDIX B: DEVICE
DIFFERENCES
Modifying, removing or adding components may
adversely affect touch performance.
Specific manufacturers and part numbers are provided
only as a guide. Equivalents can be used.
TABLE B-1: BILL OF MATERIALS
Label Quantity Value Description Manufacturer Part Number
C1 1 10 uF Capacitor – Ceramic, 10 uF, 20%, 6.3V,
X7R, 0603
AVX 06036D106MAT2A
C2 1 0.1 uF Capacitor – Ceramic, 0.1 uF, 10%, 16V,
X7R, 0603
AVX 0603YC104KAT2A
C3, C4, C5(1) 2-3 0.01 uF Capacitor – Ceramic, 0.01 uF, 10%,
50V, X7R, 0603
AVX 06035C103KAT2A
D1-D8(2) 4-8 130W Diode – Bidirectional, 130W, ESD
Protection, SOD323
NXP PESD5V0S1BA
R1 1 20 KResistor – 20 K, 1/10W, 5%, 0603 Yageo America RC0603JR-0720KL
U1 1 N/A Touch controller IC Microchip AR1011 or AR1021
Note 1: C5 is only needed for 5-wire applications.
2: D1-D8 are for ESD protection.
- 4-wire touch screen, use D1-D4
- 5-wire touch screen, use D1-D5
- 8-wire touch screen, use D1-D8
See Section 3.8 “ESD Considerations” and Section 3.9 “Noise Considerations” for important information
regarding the capacitance of the controller schematic hardware.
2009-2016 Microchip Technology Inc. DS40001393C-page 59
AR1000 SERIES RESISTIVE TOUCH SCREEN CONTROLLER
THE MICROCHIP WEBSITE
Microchip provides online support via our website at
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CUSTOMER SUPP ORT
Users of Microchip products can receive assistance
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DS40001393C-page 60 2009-2016 Microchip Technology Inc.
Information contained in this publication regarding device
applications and the like is provided only for your convenience
and may be superseded by updates. It is your responsibility to
ensure that your application meets with your specifications.
MICROCHIP MAKES NO REPRESENTATIONS OR
WARRANTIES OF ANY KIND WHETHER EXPRESS OR
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OTHERWISE, RELATED TO THE INFORMATION,
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intellectual property rights unless otherwise stated.
Trademarks
The Microchip name and logo, the Microchip logo, AnyRate,
dsPIC, FlashFlex, flexPWR, Heldo, JukeBlox, KeeLoq,
KeeLoq logo, Kleer, LANCheck, LINK MD, MediaLB, MOST,
MOST logo, MPLAB, OptoLyzer, PIC, PICSTART, PIC32 logo,
RightTouch, SpyNIC, SST, SST Logo, SuperFlash and UNI/O
are registered trademarks of Microchip Technology
Incorporated in the U.S.A. and other countries.
ClockWorks, The Embedded Control Solutions Company,
ETHERSYNCH, Hyper Speed Control, HyperLight Load,
IntelliMOS, mTouch, Precision Edge, and QUIET-WIRE are
registered trademarks of Microchip Technology Incorporated
in the U.S.A.
Analog-for-the-Digital Age, Any Capacitor, AnyIn, AnyOut,
BodyCom, chipKIT, chipKIT logo, CodeGuard, dsPICDEM,
dsPICDEM.net, Dynamic Average Matching, DAM, ECAN,
EtherGREEN, In-Circuit Serial Programming, ICSP, Inter-Chip
Connectivity, JitterBlocker, KleerNet, KleerNet logo, MiWi,
motorBench, MPASM, MPF, MPLAB Certified logo, MPLIB,
MPLINK, MultiTRAK, NetDetach, Omniscient Code
Generation, PICDEM, PICDEM.net, PICkit, PICtail,
PureSilicon, RightTouch logo, REAL ICE, Ripple Blocker,
Serial Quad I/O, SQI, SuperSwitcher, SuperSwitcher II, Total
Endurance, TSHARC, USBCheck, VariSense, ViewSpan,
WiperLock, Wireless DNA, and ZENA are trademarks of
Microchip Technology Incorporated in the U.S.A. and other
countries.
SQTP is a service mark of Microchip Technology Incorporated
in the U.S.A.
Silicon Storage Technology is a registered trademark of
Microchip Technology Inc. in other countries.
GestIC is a registered trademark of Microchip Technology
Germany II GmbH & Co. KG, a subsidiary of Microchip
Technology Inc., in other countries.
All other trademarks mentioned herein are property of their
respective companies.
© 2009-2016, Microchip Technology Incorporated, Printed in
the U.S.A., All Rights Reserved.
ISBN: 978-1-5224-0761-4
Note the following details of the code protection feature on Microchip devices:
Microchip products meet the specification contained in their particular Microchip Data Sheet.
Microchip believes that its family of products is one of the most secure families of its kind on the market today, when used in the
intended manner and under normal conditions.
There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our
knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Data
Sheets. Most likely, the person doing so is engaged in theft of intellectual property.
Microchip is willing to work with the customer who is concerned about the integrity of their code.
Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not
mean that we are guaranteeing the product as “unbreakable.”
Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection features of our
products. Attempts to break Microchip’s code protection feature may be a violation of the Digital Millennium Copyright Act. If such acts
allow unauthorized access to your software or other copyrighted work, you may have a right to sue for relief under that Act.
Microchip received ISO/TS-16949:2009 certification for its worldwide
headquarters, design and wafer fabrication facilities in Chandler and
Tempe, Arizona; Gresham, Oregon and design centers in California
and India. The Company’s quality system processes and procedures
are for its PIC® MCUs and dsPIC® DSCs, KEELOQ® code hopping
devices, Serial EEPROMs, microperipherals, nonvolatile memory and
analog products. In addition, Microchip’s quality system for the design
and manufacture of development systems is ISO 9001:2000 certified.
QUALITY MANAGEMENT S
CERTIFIED BY DNV
== ISO/TS 16949 ==
2009-2016 Microchip Technology Inc. DS40001393C-page 61
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