ATMEL AT42QT1111-MU

Features
• Sensor Keys:
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
– Up to 11 QTouch™ channels
Data Acquistion:
– Measurement of keys triggered either by a signal applied to the SYNC pin or at
regular intervals timed by the AT42QT1110's internal clock
– Keys measured sequentially for better performance, or in parallel groups for faster
operation
– Raw data for key touches can be read as a report over the SPI interface
Discrete Outputs:
– Configurable “Detect” outputs indicating individual key touch (7-key mode)
Device Setup:
– Device configuration can be stored in EEPROM
Technology:
– Patented spread-spectrum charge-transfer (direct mode)
Key Outline Sizes:
– 6 mm x 6 mm or larger (panel thickness dependent); widely different sizes and
shapes possible, including solid or ring shapes
Key Spacings:
– 7 mm center to center or more (panel thickness dependent)
Layers Required:
– One
Electrode Materials:
– Etched copper, silver, carbon, Indium Tin Oxide (ITO)
Electrode Substrates:
– PCB, FPCB, plastic films, glass
Panel Materials:
– Plastic, glass, composites, painted surfaces (low particle density metallic paints
possible)
Panel Thickness:
– Up to 10 mm glass, 5 mm plastic (electrode size dependent)
Key Sensitivity:
– Individually settable via simple commands over serial interface
Adjacent Key Suppression® (AKS™)
– Patented AKS technology to enable accurate key detection
Interface:
– Full-duplex SPI slave mode (750 KHz), “change” pin, discrete detection outputs
Moisture Tolerance Good
Power:
– 1.8V ~ 5.5V
Package:
– 32-pin 5 x 5 mm MLF RoHS compliant
– 32-pin 7 x 7 mm TQFP RoHS compliant
Signal Processing:
– Self-calibration, auto drift compensation, noise filtering, AKS technology
Applications:
– Consumer and industrial applications, such as TV, media player, etc
QTouch™ 11-key
Sensor IC
AT42QT1111-MU
AT42QT1111-AU
9571A–AT42–02/10
1. Pinout and Schematic
1.1
Pinout Configuration
SNS8K/DETECT3
SNS9/DETECT4
32 31 30 29 28 27 26 25
24
23
22
21
QT1111
20
19
18
17
9 10 11 12 13 14 15 16
QT1110
SNS8/DETECT2
SNS7/DETECT1
SNS7K/DETECT0
VSS
SNS6
SNS6K
VDD
SCK
SS
MISO
MOSI
SNS5K
SNS5
SNS4K
SNS4
SNS3K
2
SNS9K/DETECT5
CHANGE
RESET
SNS10/DETECT6
SNS0
SNS3
1
2
3
4
5
6
7
8
SNS10K/SYNC
SNS0K
SNS1
SNS1K
VDD
VSS
SNS2K
SNS2
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1.2
Pin Descriptions
Table 1-1.
I
O
Pin Listing
Pin
Name
Type
Comments
If Unused, Connect To...
1
SNS0K
I/O
Sense Pin
Leave open
2
SNS1
I/O
Sense Pin
Leave open
3
SNS1K
I/O
Sense Pin
Leave open
4
Vdd
P
Power
–
5
Vss
P
Supply Ground
–
6
SNS2K
I/O
Sense Pin
Leave open
7
SNS2
I/O
Sense Pin
Leave open
8
SNS3
I/O
Sense Pin
Leave open
9
SNS3K
I/O
Sense Pin
Leave open
10
SNS4
I/O
Sense Pin
Leave open
11
SNS4K
I/O
Sense Pin
Leave open
12
SNS5
I/O
Sense Pin
Leave open
13
SNS5K
I/O
Sense Pin
Leave open
14
SS
I
Enable SPI
Vss via 100 k resistor to enable SPI
Vdd via 100 k resistor to disable SPI
15
MOSI
I
SPI Data In
Leave open
16
MISO
O
SPI Data Out
Leave open
17
SCK
I
SPI Clock
Leave open
18
Vdd
P
Power
–
19
SNS6K
I/O
Sense Pin
Leave open
20
SNS6
I/O
Sense Pin
Leave open
21
Vss
P
Supply Ground
–
22
SNS7K/DETECT0
I/O
Sense Pin/Key Status Indicator
Leave open
23
SNS7/DETECT1
I/O
Sense Pin/Key Status Indicator
Leave open
24
SNS8/DETECT2
I/O
Sense Pin / Key Status Indicator
Leave open
25
SNS8K/DETECT3
I/O
Sense Pin / Key Status Indicator
Leave open
26
SNS9/DETECT4
I/O
Sense Pin / Key Status Indicator
Leave open
27
SNS9K/DETECT5
I/O
Sense Pin / Key Status Indicator
Leave open
28
CHANGE
OD
Touch Event Indicator
Leave open
29
RESET
I
Reset
Vdd
30
SNS10/DETECT6
I/O
Sense Pin / Key Status Indicator
Leave open
31
SNS10K/SYNC
I/O
Sense Pin / Synchronization Input
Vdd or Vss via 100 k resistor
32
SNS0
I/O
Sense Pin
Leave open
Input only
Output only, push-pull
I/O
OD
Input and output
Open drain output
P
Ground or power
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1.3
Schematics
Typical Circuit: 7 keys With Detect Outputs and No External Trigger
Vunreg
VREG
QT1111
Figure 1-1.
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Figure 1-2.
Typical Circuit: 11 Keys With No External Trigger
Vunreg
VREG
QT1111
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Figure 1-3.
Typical Circuit: 10 Keys With External Trigger (SYNC Mode)
Vunreg
VREG
QT1111
Suggested voltage regulator manufacturers:
• Torex (XC6215 series)
• Seiko (S817 series)
• BCDSemi (AP2121 series)
Re Figure 1-1, Figure 1-2 and Figure 1-3 check the following sections for component values:
• Section 3.1 on page 8: Cs capacitors (Cs0 – Cs10)
• Section 3.2 on page 8: Sample resistors (Rs0 – Rs10)
• Section 3.5 on page 9: Voltage levels
• Section 3.3 on page 8: LED traces
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2. Overview of the AT42QT1111
2.1
Introduction
The AT42QT1111 (QT1111) is a digital burst mode charge-transfer (QT™) capacitive sensor
driver designed for any touch-key applications.
The keys can be constructed in different shapes and sizes. Refer to the Touch Sensors Design
Guide and Application Note QTAN0002, Secrets of a Successful QTouch™ Design, for more
information on construction and design methods (both downloadable from the Atmel® website).
The device includes all signal processing functions necessary to provide stable sensing under a
wide variety of changing conditions, and the outputs are fully debounced. Only a few external
parts are required for operation.
The QT1111 modulates its bursts in a spread-spectrum fashion in order to suppress heavily the
effects of external noise, and to suppress RF emissions.
2.2
Configurations
The QT1111 is designed as a versatile device, capable of various configurations. There are two
basic configurations for the QT1111:
• 11-key QTouch. The device can sense up to 11 keys.
• 7-key QTouch with individual outputs for each key. The device can sense up to 7 keys and
drive the matching Detect outputs to a user-configurable PWM.
Both configurations allow for a choice of acquisition modes, thus providing a variety of
possibilities that will satisfy most applications (see the following sections for more information).
Additionally, the SYNC line can be used as an external trigger input. Note that in 11-key mode
the SYNC line replaces one key, thus allowing only 10 keys.
See Section 4.7 on page 18 for more information.
2.3
Guard Channel
The device has a guard channel option (available in all key modes), which allows one key to be
configured as a guard channel to help prevent false detection. See Section 4.9 on page 19 for
more information.
2.4
Self-test Functions
The QT1111 has two types of self-test functions:
• Internal Hardware tests – check for hardware failures in the device’s internal memory.
• Functional checks – confirm that the device is operating within expected parameters.
See Section 4.10 on page 20 for more information.
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3. Wiring and Parts
3.1
Cs Sample Capacitors
Cs0 – Cs10 are the charge sensing sample capacitors. Normally they are identical in nominal
value. The optimal Cs values depend on the thickness of the panel and its dielectric constant.
Thicker panels require larger values of Cs. Values can be in the range 2.2 nF (for faster
operation) to 33 nF (for best sensitivity); typical values are 4.7 nF to 10 nF.
The value of Cs should be chosen so that a light touch on a key produces a reduction of
~20 to 30 in the key signal value (see Section 6.8 on page 26). The chosen Cs value should
never be so large that the key signals exceed ~1000, as reported by the chip in the debug data.
The Cs capacitors must be X7R or PPS film type, for stability. For consistent sensitivity, they
should have a 10 percent tolerance. Twenty percent tolerance may cause small differences in
sensitivity from key to key and unit to unit. If a key is not used, the Cs capacitor may be omitted.
3.2
Rs Resistors
The series resistors Rs0 – Rs10 are inline with the electrode connections and should be used to
limit electrostatic discharge (ESD) currents and to suppress radio frequency (RF) interference.
Values should be approximately 2 kto 20 k each; a typical value is 4.7 k.
Although these resistors may be omitted, the device may become susceptible to external noise
or radio frequency interference (RFI). For details of how to select these resistors see the
Application Note QTAN0002, Secrets of a Successful QTouch™ Design, downloadable from the
Touch Technology area of Atmel’s website, www.atmel.com.
3.3
LED Traces and Other Switching Signals
Digital switching signals near the sense lines can induce transients into the acquired signals,
deteriorating the SNR performance of the device. Such signals should be routed away from the
sensing traces and electrodes, or the design should be such that these lines are not switched
during the course of signal acquisition (bursts).
LED terminals which are multiplexed or switched into a floating state, and which are within, or
physically very near, a key (even if on another nearby PCB) should be bypassed to either Vss or
Vdd with at least a 1 nF capacitor. This is to suppress capacitive coupling effects which can
induce false signal shifts. The bypass capacitor does not need to be next to the LED, in fact it
can be quite distant. The bypass capacitor is noncritical and can be of any type.
LED terminals which are constantly connected to Vss or Vdd do not need further bypassing.
3.4
PCB Cleanliness
Modern no-clean flux is generally compatible with capacitive sensing circuits.
CAUTION: If a PCB is reworked to correct soldering faults relating to the QT1111, or
to any associated traces or components, be sure that you fully understand the nature
of the flux used during the rework process. Leakage currents from hygroscopic ionic
residues can stop capacitive sensors from functioning. If you have any doubts, a
thorough cleaning after rework may be the only safe option.
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3.5
Power Supply
See Section 8.2 on page 38 for the power supply range. If the power supply fluctuates slowly
with temperature, the device tracks and compensates for these changes automatically with only
minor changes in sensitivity. If the supply voltage drifts or shifts quickly, the drift compensation
mechanism is not able to keep up, causing sensitivity anomalies or false detections.
The usual power supply considerations with QT parts apply to the device. The power should be
clean and come from a separate regulator if possible. However, this device is designed to
minimize the effects of unstable power, and, except in extreme conditions, should not require a
separate Low Dropout (LDO) regulator.
See underneath Figure 1.3 on page 4 for suggested regulator manufacturers.
Caution: A regulator IC shared with other logic can result in erratic operation and is
not advised.
A single ceramic 0.1 µF bypass capacitor, with short traces, should be placed very
close to the power pins of the IC. Failure to do so can result in device oscillation,
high current consumption, erratic operation etc.
It is assumed that a larger bypass capacitor (like1 µF) is somewhere else in the power circuit; for
example, near the regulator.
3.6
MLF Package Restrictions
The central pad on the underside of the MLF chip should be connected to ground. Do not run
any tracks underneath the body of the chip, only ground. Figure 3-1 shows an example of
good/bad tracking.
Figure 3-1.
Examples of Good and Bad Tracking
Example of GOOD Tracking
Example of BAD Tracking
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4. Detailed Operations
4.1
4.1.1
Communications
Introduction
All communication with the device is carried out over the Serial Peripheral Interface (SPI). This is
a synchronous serial data link that operates in full-duplex mode. The host communicates with
the QT controller over the SPI using a master-slave relationship, with the QT1111 acting in slave
mode.
4.1.2
SPI Operation
The SPI uses four logic signals:
• Serial Clock (SCK) – output from the host.
• Master Output, Slave Input (MOSI) – output from the host, input to the QT controller. Used by
the host to send data to the QT controller.
• Master Input, Slave Output (MISO) – input to the host, output from the QT controller. Used by
the QT device to send data to the host.
• Slave Select (SS) – active low output from the host.
At each byte, the master pulls SS low and generates 8 clock pulses on SCK. With these 8 clock
pulses, a byte of data is transmitted from the master to the slave over MOSI, most significant bit
(msb) first.
Simultaneously a byte of data is transmitted from the slave to the master over MISO, also most
significant bit first.
The slave reads the status of MOSI at the leading edge of each clock pulse, and the master
reads the slave’s data from MISO at the trailing edge.
The QT1111 requires that the clock idles “high”, meaning that the data on MOSI and MISO pins
are set at the falling edges and sampled at the rising edges.
That is:
Clock polarity CPOL = 1
Clock phase CPHA = 1
The QT1111 SPI interface can operate at any SCK frequency up to 750 KHz.
In multibyte communications, the master must pause for a minimum delay of 300 µs between
the completion of one byte exchange and the beginning of the next.
Note that the number of bytes to be transmitted depends on the initial command sent by the
host. This sets the mode on the QT1111 so that the QT1111 knows how to respond to, or how to
interpret, the following bytes. If there is a delay of >100 ms between bytes while the QT1111 is
waiting for data, or waiting to send data, then the incomplete transmission is discarded and the
device resets its SPI state machine. It will then interpret the next byte it receives as a fresh
command.
When the QT1111 SPI interface is receiving a new command, it returns the “Idle” status code
(0x55) on MISO during the first byte exchange to indicate to the master that it is in the correct
state for receiving instructions.
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4.1.3
CRC Bytes
If enabled, a CRC checking procedure is implemented on all communications between the SPI
master and the QT1111. In this case, each command or report request sent by the master must
have a byte appended containing the CRC checksum of the data sent. The QT1111 will not
respond to commands until the CRC byte has been received and verified.
Sample C code showing the algorithm for calculating the CRC of the data can be found in
Appendix A.
When the QT1111 is expecting a CRC byte, it returns (on MISO) the calculated CRC byte which
it expects to receive. This is sent simultaneously with the QT1111 receiving the CRC byte from
the master (that is, during the same byte exchange). This allows both devices to confirm that the
data was sent correctly.
All data returned by the QT1111 is also be followed by a CRC byte, allowing the master to
confirm the integrity of the data transmission.
4.1.4
SPI Commands
There are three types of communication between the SPI master and the QT1111:
• Control commands (see Section 5 on page 22)
– To send control instructions to the QT1111
• Report requests (see Section 6 on page 24)
– To reading status information from the QT1111
• Setup commands (see Section 7 on page 28)
– To set configuration options (“Set” instructions)
– To read configuration options (“Get” instructions)
Additionally the “Null” command (0x00) is transmitted by the host device as it is receiving data
from the QT1111.
4.1.4.1
Control Commands
A control command is an instruction sent to the QT1111 that controls operations of the device,
and for which no response is required. Examples of control commands are: “Reset”, “Calibrate”,
“Send Setups”.
With the exception of “Send Setups”, control commands normally require a single byte
exchange, unless CRC checking is enabled, in which case a second byte must be transmitted
by the host with the calculated CRC of the command byte.
Figure 4-1.
Sleep Command – CRC Disabled
Host (Sends on MOSI)
Device (Responds on MISO)
Command: 0x05
Response: 0x55 (“Idle” – Fresh Command)
Simultaneous
Transmission
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Figure 4-2.
Sleep Command – CRC Enabled
Host (Sends on MOSI)
Device (Responds on MISO)
Command: 0x05
Response: 0x55 (“Idle” – Fresh Command)
Simultaneous
Transmission
Command CRC: 0x3F
Response: 0x3F (Expected Command CRC)
When the “Send Setups” command is received, the QT1111 stops measurement of QTouch
sensors and waits for 42 bytes of data to be sent. Only when all 42 bytes have been received
(and the CRC byte, if CRC is enabled), the QT1111 applies all the settings to RAM and resumes
measurement. In this case, if CRC is enabled, the CRC byte is calculated for all the data sent by
the host, including the command byte 0x01.
Control Commands are specified in detail in Section 5 on page 22.
4.1.5
Report Requests
Report Requests are sent by the Host to instruct the QT1111 to return status information. The
host sends the appropiate “Report Request” command, then transmits Null bytes on MOSI while
the QT1111 returns the report data on MISO.
Figure 4-3.
All Keys Report – CRC Disabled
Host (Sends on MOSI)
Device (Responds on MISO)
Command: 0xC1
Response: 0x55 (“Idle” – Fresh Command)
Simultaneous
Transmission
Null: 0x00
Key Status Report Byte 0
Null: 0x00
Key Status Report Byte 1
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For example, Figure 4-3 on page 12 shows the exchange that takes place to read the 2-byte “All
Keys” report. In this exchange, the host sends:
0xC1 — 0x00 — 0x00
and the QT1110 returns (simultaneously):
0x55 — Report Byte 0 — Report Byte 1
If CRC is enabled, this exchange is extended to 5 bytes, as shown in Figure 4-4.
Figure 4-4.
All Keys Report – CRC Enabled
Host (Sends on MOSI)
Device (Responds on MISO)
Command: 0xC1
Response: 0x55 (“Idle” – Fresh Command)
Simultaneous
Transmission
Command CRC: 0x94
Response: 0x94 (Expected Command CRC)
Null: 0x00
Key Status Report Byte 0
Null: 0x00
Key Status Report Byte 1
Null: 0x00
Report CRC: 0x??
4.1.5.1
Set Instructions
Set Instructions are 2-byte transmissions by the host that are used to send settings to individual
locations in the device memory map.
At the first byte, the QT1111 returns 0x55 (“Idle”) to confirm that it will interpret the byte as a new
command. At the second byte, the QT1111 returns the “Set” command it has just received.
For example, to set the “Positive Recalibration Delay” to 1920 ms, address 5 in the memory map
is set to 12 (0x0C). This is done with the “Set” command for address 5 (command code 0x95),
as shown in Figure 4-5 on page 14.
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Figure 4-5.
Positive Recalibration Delay Set Instruction – CRC Disabled
Host (Sends on MOSI)
Device (Responds on MISO)
Command: 0x95
Response: 0x55 (“Idle” – Fresh Command)
Simultaneous
Transmission
“Set” Data: 0x0C
Response: 0x95 (Command Just Received)
With CRC Enabled, a CRC byte is also required (Figure 4-6). This is calculated for the two
transmitted bytes (that is, the “Set” command and the data byte).
For example, for the sequence shown in Figure 4-5 (0x95 — 0x0C), the CRC Byte is 0x9F. As is
the case with the other command types, when the QT1111 is expecting a CRC byte from the
host, it calculates that byte in advance and returns the expected value to the host in the same
transmission as the host sends the CRC byte.
The sent data is not applied to the memory location until the CRC byte has been received and
verified.
Figure 4-6.
Positive Recalibration Delay Set Instruction – CRC Enabled
Host (Sends on MOSI)
Device (Responds on MISO)
Command: 0x95
Response: 0x55 (“Idle” – Fresh Command)
Simultaneous
Transmission
“Set” Data: 0x0C
Response: 0x95 (Command Just Received)
Command CRC: 0x9F
Response: 0x9F (Expected CRC)
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4.1.5.2
Get Instructions
Get instructions are instructions that read the data from a location in the QT1111 memory map.
Figure 4-7.
Positive Recalibration Delay Get Instruction – CRC Disabled
Host (Sends on MOSI)
Device (Responds on MISO)
Command: 0xD5
Response: 0x55 (“Idle” – Fresh Command)
Simultaneous
Transmission
Null: 0x00
“Get” Data: 0x0C (Positive Recalibration Delay)
The host sends the appropriate “Get” command, followed by a “Null” byte. The QT1111 returns
the contents of the addressed memory location.
Figure 4-7 on page 15 shows the exchange for a report on the positive recalibration delay
(assuming that the data byte is 0x0C).
With CRC Enabled, this exchange takes 4 bytes, with a command CRC transmitted by the host
and a report CRC returned by the QT1111 (see Figure 4-8).
Figure 4-8.
Positive Recalibration Delay Get Instruction – CRC Enabled
Host (Sends on MOSI)
Device (Responds on MISO)
Command: 0xD5
Response: 0x55 (“Idle” – Fresh Command)
Simultaneous
Transmission
Command CRC: 0x68
Response: 0x68 (Expected Command CRC)
Null: 0x00
“Get” Data: 0x0C (Positive Recalibration Delay)
Null: 0x00
“Get” CRC: 0xA3
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4.1.6
4.1.6.1
Quick SPI Mode
Introduction
In Quick SPI Mode, the QT1111 sends a 7-byte key report at each exchange. No host
commands are required over SPI in this mode; the host clocks the data bytes out in sequence.
4.1.6.2
Quick SPI Report
The 7 report bytes are in the format given in Table 4-1.
Table 4-1.
Byte
Device Status Report Format
Description
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
0
Counter
Counter – increments from 0 to 255
1
Detect status, channels 0 – 3
Channel 3
Channel 2
Channel 1
Channel 0
2
Detect status, channels 4 – 7
Channel 7
Channel 6
Channel 5
Channel 4
3
Detect status, channels 8 – 10
Reserved
Channel 10
Channel 9
Channel 8
4
Error status, channels 0 – 3
Channel 3
Channel 2
Channel 1
Channel 0
5
Error status, channels 4 – 7
Channel 7
Channel 6
Channel 5
Channel 4
6
Error status, channels 8 – 10
Reserved
Channel 10
Channel 9
Channel 8
where:
• Byte 0 is a counter that increments from 0 to 254 on successive exchanges to confirm that
firmware is operating correctly.
• Bytes 1 – 3 indicate the detect status of channels 0 – 3, 4 – 7 and 8 – 10 respectively (two
bits per channel), as follows:
– 00 = Channel not in detect
– 01 = Channel in detect
– 10 = Not Allowed
– 11 = Invalid Signal (Channel disabled)
• Bytes 4 – 6 indicate the error status of channels 0 – 3, 4 – 7 and 8 – 10 respectively (two bits
per channel), as follows:
– 00 = No error
– 01 = Not allowed
– 10 = Error on channel
– 11 = Invalid signal (channel disabled)
4.1.6.3
Commands in Quick SPI Mode
Only two host commands are recognized under Quick SPI mode. These are shown in Table 4-2.
Table 4-2.
Host Commands in Quick SPI Mode
Command
Code
Purpose
Store to EEPROM
0x0A
Allows for “Quick SPI mode” to be stored as the
default start-up mode
Enable Full SPI
0x36
Enables full SPI mode
CRC checking is not implemented in Quick SPI mode for host commands or return data.
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4.1.6.4
Quick SPI Mode timing
In Quick SPI mode, the minimum time between byte exchanges is reduced to 100 µS.
If a pause in communications of 100 ms is detected during reading of the 7-byte report, the
QT1111 resets the exchange, and on the next byte read it returns byte 0 of the report.
4.2
Reset
The QT1111 can be reset using one of two methods:
• Hardware reset: An external reset logic line can be used if desired, fed into the RESET pin.
However, under most conditions it is acceptable to tie RESET to Vdd.
• Software reset: A software reset can be forced using the “Reset” control command.
For both methods, the device will follow the same initialization sequence. If there any saved
settings in the EEPROM, these are loaded into RAM. Otherwise the default settings are applied.
Note:
4.3
The SPI interface becomes active after the QT1111 has completed its startup sequence,
taking approximately 320 ms after power on/reset.
Sleep Mode
The QT1111 can be put into a very low power sleep mode (typically < 2 µA). During sleep mode,
no keys are measured and the DETECT outputs are all put into high impedience mode to
minimize current consumption. The device remains in sleep mode until a falling edge is detected
on either the SS pin or the CHANGE pin. When the QT1111 wakes from sleep mode, it
continues to operate as it was before it was put into sleep mode. The QT1111 requires
approximately 100 µs to wake from sleep mode and will not respond correctly to SPI
communications until the wake-up procedure is complete. The low level on the SS or CHANGE
pin that is used to wake the device must be maintained for 100 µs to ensure correct operation.
Note:
4.4
If the device is set to sleep mode for an extended period, the host should initiate a
recalibration immediately after waking the QT1111.
Calibration
The device can be forced to recalibrate the sensor keys at any time. This can be useful where,
for example, a portable device is plugged into mains power, or during product development
when settings are being tuned.
The QT1111 can also be configured to automatically recalibrate if it remains in detection for too
long. This avoids keys becoming “stuck” after a prolonged period of uninterrupted detection. See
Section 7.17 on page 37 for details.
4.5
CHANGE Pin
The CHANGE pin can be configured using the Comms Options setup byte (see Section 7.5 on
page 30) to act in one of two modes:
• Data mode
– The CHANGE pin is asserted (pulled low) when the detection status of a key
changes from that last sent to the host; that is when a key-touch or key-release event
occurs.
– The CHANGE pin is pulled low when a key’s status changes and is only released
when the “Send All keys” report is requested (0xC1), or the key status information
bytes are read in Quick SPI mode (see Section 7.5 on page 30).
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• Touch mode
– The CHANGE pin is pulled low when one or more keys are in detect. The CHANGE
pin remains low as long as there is a key in detect, regardless of communications.
– The CHANGE pin is released when there are no keys in detect. No host
communications are required to release the CHANGE pin.
4.6
Stand-alone Mode
The QT1111 can operate in a stand-alone mode without the use of the SPI interface. The
settings are loaded from EEPROM and the device operates in 7-key mode using the Detect
outputs.
4.7
4.7.1
Key Modes
11-key Mode
In 11-key mode, the device can sense up to 11 keys. Alternatively, one key can be replaced by
the SYNC line as an external trigger input (see Section 4.8.2 on page 19).
11-key mode is configured by setting the “MODE” bit in the Device Mode setup byte (see
Section 7.4 on page 29).
Key acquisition can be triggered in one of two ways: using the internal clock to trigger acquisition
either at a fixed repetition period or in a continuous “free run” mode (see Section 4.8.1), or using
the SYNC pin to provide an external trigger (see Section 4.8.2 on page 19),
4.7.2
7-key Mode
In 7-key mode, the detect outputs DETECT0 to DETECT6 become active on pins 22–27 and 30.
These outputs provide configurable PWM signals that indicate when each of the keys is
touched.
7-key mode is configured by clearing the “MODE” bit in the Device Mode setup byte (see
Section 7.4 on page 29).
Each DETECT output can be individually configured to output a PWM signal while the matching
key is in detect or out of detect. This signal can be one of nine levels, ranging from low
(PWM = 0 percent) to high (PWM = 100 percent). This allows for the use of an indicating LED.
This is achieved by enabling the appropriate bit in the Key to LED setup byte (see Section 7.14
on page 35), and setting the desired outputs levels or PWMs in setup addresses 9 to 15 (see
Section 7.12 on page 33).
4.8
Trigger Modes
4.8.1
Timed Trigger
In 11-key mode, The QT1111 can be configured to use the internal clock as a timed trigger. In
this case, the QT1111 is configured with a cycle period, such that each acquisition cycle starts a
specified length of time after the start of the previous cycle. If the cycle period is set to “0”, each
acquisition cycle starts as soon as the previous one has finished, resulting in the acquisition
cycles running back-to-back in a “free run” mode.
The use of a timed trigger, and the cycle period to be used, is set in the Device Mode setup byte
(see Section 7.4 on page 29).
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4.8.2
Synchronized Trigger
In 11-key mode, if a time trigger is not enabled, the QT1111 operates in “synchronized” mode. In
this mode, SNS10K is used as a SYNC pin to trigger key acquisition, rather than using the
device’s internal clock. In this case the maximum number of keys is reduced to 10.
The SYNC pin can use one of two methods to trigger key measurements, selectable via bit 4 of
the Device Mode setup byte (see Section 7.4 on page 29): Low Level and Rising Edge.
With the Low Level method the QT1111 operates in “free run” mode for as long as the SYNC pin
is read as a logical “0”. When the SYNC pin goes high, the current measurement cycle will be
finished and no more key measurements will be taken until the SYNC pin goes low again.
The low level trigger should be a minimum of 1 ms so that there is sufficient time for the device
to detect the low level.
With the Rising Edge method all enabled keys are measured once when a rising edge is
detected on the SYNC pin. This allows key measurements to be synchronized to an external
event or condition.
For example, the SYNC pin can be used by the host to synchronize several devices to each
other. This would ensure that only one of the devices outputs pulses at any given time and
signals from one QT1111 do not interfere with the measurements from another.
Another use for synchronizing to the rising edge is to steady the signals when the device is
running off a mains transformer with insufficient mains frequency filtering that is causing a 50Hz
or 60Hz ripple on Vdd. If the mains voltage is scaled down with a simple voltage divider and
connected to the SYNC pin, then the key measurement can be triggered by the rising edge
detected at a positive going zero-crossing. Note that in this case, each key signal will be taken at
the same point in the cycle, so Vdd will be the same at each measurement for a given key and
the signals will be steadier.
4.9
Guard Channel Option
The device has a guard channel option (available in all key modes), which allows one key to be
configured as a guard channel to help prevent false detection (see Figure 4-9 on page 20).
Guard channel keys should be more sensitive than the other keys (physically bigger or larger
Cs), subject to burst length limitations (see Section 4.11.2 on page 21).
With guard channel enabled, the designated key is connected to a sensor pad which detects the
presence of touch and overrides any output from the other keys using the chip’s AKS feature.
The guard channel option is enabled by the Guard Key setup byte (see Section 7.5 on page 30).
With the guard channel not enabled, all the keys work normally.
Note:
If a key is already “in detect” when the guard channel becomes active, that key will
remain in detect and the guard key will not activate until the active key goes out of
detect.
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Figure 4-9.
Guard Channel Example
Key Pad Formed
of Six Keys
Guard Channel
Formed of One Key
4.10
4.10.1
Self-test Functions
Internal Hardware Tests
Internal hardware tests check for hardware failure in the device’s internal memory areas and
data paths. Any failure detected in the function or contents of application ROM, RAM or registers
causes the device to reset itself.
The application code is scanned with a CRC check routine to confirm that the application data is
all correct.
The RAM and registers are checked periodically (every 10 seconds) for dynamic and static
failures.
4.10.2
Functional Checks
Functional checks confirm that the device is operating within expected parameters; any failure
detected in these tests is notified to the system host. The device will continue to operate in the
event that such functional failures are detected.
The functional tests are:
• Check that the channel-measurement signals are within the defined range.
• Confirm that data stored in the EEPROM is valid.
These tests are carried out as the particular functions are used. For example, the EEPROM is
checked when the device attempts to load data from EEPROM, and the channel signals are
checked when a measurement is carried out.
Note:
4.11
4.11.1
If a particular channel is unused, the threshold of that channel should be set to 0 to
prevent the incorrect reporting of the unused channel as being in an error state.
Signal Processing
Detection Integrator
The device features a detection integration mechanism, which acts to confirm a detection in a
robust fashion. A per-key counter is incremented each time the key has exceeded its threshold.
When this counter reaches a preset limit the key is finally declared to be touched. For example,
if the DI limit is set to 10, then a key’s signal must fall by more than the key threshold, and
remain below that level for 10 acquisitions, before the key is declared to be touched.
Similarly, the DI is applied to a key that is going out of detect: it must take 10 acquisitions where
the signal has not exceeded its detect threshold before it is declared to leave touch.
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4.11.2
Burst Length Limitations
The maximum burst length is 2048 pulses. The recommended design is to use a capacitor that
gives a signal of <1000 pulses.
The number of pulses in the burst can be obtained by reading the key signal (that is, the number
of pulses to complete measurement of the key’s signal) over the SPI interface (see Section 6.8
on page 26). Alternatively, a scope can be used to measure the entire burst, and then the burst
length divided by the time for a single pulse.
Note that the keys are independent of each other. It is therefore possible, for example, to have a
signal of 100 on one key and a signal of 1000 on another.
4.11.3
Adjacent Key Suppression Technology
The device includes Atmel’s patented Adjacent Key Suppression (AKS) technology to allow the
use of tightly spaced keys on a keypad with no loss of selectability by the user.
AKS is enabled or disabled for each key individually; only one key out of those enabled for AKS
may be reported as touched at any one time. The first key touched dominates and stays in
detect until it is released, even if another stronger key is reported. Once it is released, the next
strongest key is reported. If two keys are simultaneously detected, the strongest key is reported,
allowing a user to slide a finger across multiple keys with only the dominant key reporting touch.
Each key can be enabled for AKS processing via the AKS mask (see Section 7.11 on page 33).
Keys outside the group of enabled keys may be in detect simultaneously.
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5. Control Commands
5.1
Introduction
The QT1111 control commands are those commands that affect the device operation.
The control commands are listed in Table 5-1 and are described individually in the following
sections.
Table 5-1.
Command
Code
Note
Send Setups
0x01
Configures the device to receive setup data
Calibrate All
0x03
Calibrates all keys
Reset
0x04
Resets the device
Sleep
0x05
Sleep (dead) mode
Store to EEPROM
0x0A
Stores RAM setups to EEPROM
Restore from EEPROM
0x0B
Copies EEPROM setups to RAM (automatically done at
startup)
Erase EEPROM
0x0C
Erases EEPROM setups
Recover EEPROM
0x0D
Restores last EEPROM settings (after erase)
Calibrate Key 'k'
0x1k
Calibrates one key (key k)
Note:
5.2
Control Commands
Commands are implemented immediately upon reception, so a suitable delay is
required for the operation to be completed before communications can be
re-established.
Send Setups (0x01)
This command initiates the upload of the full settings table to the QT1111 (see Section 7 on
page 28).
When this command is received, the QT1111 stops key measurement and waits until 42 bytes of
setup data have been received. Key acquisition will restart after all the setup data has been
received.
If enabled, a CRC check byte is transmitted (both ways) after the 42 bytes to confirm that they
have been received correctly.
If CRC checking is not enabled, it is recommended that the host request a dump of setup data
from the QT1111, and confirms that the data correctly matches the data sent.
The host must wait for at least 300 µs for the operation to be completed before communications
can be re-established.
5.3
Calibrate All (0x03)
This command initiates the recalibration of all sensor keys.
The host must wait for at least 300 µs for the operation to be completed before communications
can be re-established.
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5.4
Reset (0x04)
The Reset command forces the QT1111 to reset. If the setups data is present in the EEPROM,
the setups are loaded into the device. Otherwise default settings are applied.
The host must wait for at least 160 ms for the operation to be completed before communications
can be re-established.
5.5
Sleep (0x05)
The Sleep command puts the device into sleep mode (see Section 4.3 on page 17).
The host must wait for at least 300 µs after a low signal is applied to the SS or CHANGE pin to
wake the device before communications can be re-established.
5.6
Store to EEPROM (0x0A)
Stores the current RAM contents to the QT1111’s internal EEPROM. When the device is reset, it
will automatically reload these settings.
The host must wait for at least 200 ms for the operation to be completed before communications
can be re-established.
5.7
Restore from EEPROM (0x0B)
Settings stored in EEPROM are automatically loaded into RAM when the device is reset. If
desired, these settings can be re-loaded into RAM using the ‘Restore from EEPROM’ command.
The host must wait for at least 150 ms for the operation to be completed before communications
can be re-established.
5.8
Erase EEPROM (0x0C)
This command erases the settings stored in EEPROM and then resets the QT1111. This causes
the QT1111 to revert to its default settings.
The host must wait for at least 50 ms for the operation to be completed before communications
can be re-established.
5.9
Recover EEPROM (0x0D)
This command “undeletes” the setup data that was previously stored in the device’s EEPROM
and has been erased using the “Erase EEPROM” command.
Note:
If valid settings have not previously been stored in the device EEPROM, the QT1111
continues to operate under the default settings.
The host must wait for at least 50 ms for the operation to be completed before communications
can be re-established.
5.10
Calibrate Key (0x1k)
This command recalibrates the key specified by “k”. For example, to calibrate key 4, the host
sends “0x14”; to calibrate key 10, the host sends “0x1A”.
The host must wait for at least 300 µs for the operation to be completed before communications
can be re-established.
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6. Report Requests
6.1
Introduction
The host can request reports from the QT1111, as summarized in Table 6-1.
Table 6-1.
Report Requests
Command
Code
Note
Data Returned
Send First Key
0xC0
Returns the first detected key
Send All keys
0xC1
Returns all keys
2-byte bitfield
Device Status
0xC2
Returns the device status
1-byte bitfield
EEPROM CRC
0xC3
Returns the EEPROM CRC
1 byte
RAM CRC
0xC4
Returns the RAM CRC
1 byte
Error Keys
0xC5
Returns the error keys
2-byte bitfield
Signal for Key “k”'
0x2k
Returns the signal for key “k”
2-byte number
Reference for Key “k”
0x4k
Returns the reference for key “k”
2-byte number
Status for Key “k”
0x8k
Returns error conditions/touch indication
1 byte
Detect Output States
0xC6
Returns the detect output states
1 byte
Last Command
0xC7
Returns the last command sent to QT1111
1 byte
Setups
0xC8
Returns the setup data
42 bytes
Device ID
0xC9
Returns the device ID
1 byte
Firmware Version
0xCA
Returns the firmware version
1 byte
1 byte
Note that SPI communications are full-duplex, so the host must transmit on the MOSI pin to
keep the communications active, while reading data from the QT1111 on the MOSI pin. Failure
to do this within 100 ms will cause the device to assume that the exchange has been abandoned
and reset the SPI interface. The host should therefore send one or two “NULL” bytes, as
appropriate, on the MOSI line as it receives the 1- or 2-byte report data from the device.
6.2
First Key (0xC0)
This command returns 1-byte report in the format shown in Table 6-2.
Table 6-2.
Byte 0
Send First Key Report Format
Bit 7
Bit 6
Bit 5
DETECT
NUMKEY
ERROR
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
KEY_NUM
DETECT: 0 = no key in detect; 1 = there is a key in detect.
NUMKEY: indicates the number of keys in detect:
0 = only one key is in detect (specified by “KEY_NUM”)
1 = more than one key in detect.
ERROR: 0 = there are no keys in an error state; 1 = at least one key is in error state.
KEY_NUM: the key number (0 to 10) of the key in detect (if there is only one), or the number of
the first key to go into detection when there are more than one.
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6.3
All Keys (0xC1)
Returns a 2-byte bit-field report indicating the detection status of all 11 keys.
Table 6-3.
Send All Keys Report Format
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Byte 0
Byte 1
KEY_7
KEY_6
KEY_5
KEY_4
KEY_3
Bit 2
Bit 1
Bit 0
KEY_10
KEY_9
KEY_8
KEY_2
KEY_1
KEY_0
KEY_n: 0 = key n out of detect, 1 = key n in detect (where n is 0–10).
6.4
Device Status (0xC2)
This command returns a 1-byte bit-field report indicating the overall status of the QT1111.
Table 6-4.
Byte 0
Device Status Report Format
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
1
DETECT
CYCLE
ERROR
CHANGE
EEPROM
RESET
GUARD
Bits 7 is always 1; the other bits are as follows:
DETECT: 0 = no key in detect, 1 = at least 1 key in detect.
CYCLE: 0 = cycle time is good, 1 = cycle time over-run. A cycle time over-run occurs when it
takes longer to measure and process all the keys than the assigned cycle time.
ERROR: 0 = no key in error state, 1 = at least 1 key in error.
CHANGE: 0 = CHANGE pin is asserted, 1 = CHANGE pin is floating.
EEPROM: 0 = EEPROM is good, 1 = EEPROM has an error. If there are no settings stored in
EEPROM, the EEPROM error bit is set and a zero EEPROM CRC is returned.
RESET: set to 1 after power-on or reset, cleared when “Device Status” is read.
GUARD: 0 = guard channel is not in detect, 1 = guard channel is active or in detect. This bit will
be zero if the guard channel is not enabled.
6.5
EEPROM CRC (0xC3)
This command returns a 1-byte CRC checksum for the setup data in EEPROM.
6.6
RAM CRC (0xC4)
This command returns a 1-byte CRC checksum for the setup data in RAM.
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6.7
Error Keys (0xC5)
This command returns a 2-byte bit-field report indicating the error status of all 11 keys. Note that
disabled keys do not report errors.
Table 6-5.
Send All Keys Report Format
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Byte 0
Byte 1
KEY_7
KEY_6
KEY_5
KEY_4
KEY_3
Bit 2
Bit 1
Bit 0
KEY_10
KEY_9
KEY_8
KEY_2
KEY_1
KEY_0
KEY_n: 0 = key n status good, 1 = key n in error (where n is 0–10).
6.8
Signal for Key “k” (0x2k)
This command returns a 2-byte report containing the most recent measured signal for key “k”.
The signal is returned as a 16-bit number, MSB first.
Table 6-6.
Signal for Key “k” Report Format
Bit 7
6.9
Bit 6
Bit 5
Bit 4
Bit 3
Byte 0
Signal MSB
Byte 1
Signal LSB
Bit 2
Bit 1
Bit 0
Reference for Key “k” (0x4k)
This command returns a 2-byte report containing the reference signal for key “k”. The reference
is returned as a 16-bit number, MSB first.
Table 6-7.
Reference for Key “k” Report Format
Bit 7
6.10
Bit 6
Bit 5
Bit 4
Bit 3
Byte 0
Reference MSB
Byte 1
Reference LSB
Bit 2
Bit 1
Bit 0
Bit 2
Bit 1
Bit 0
AKS_EN
CAL
KEY_EN
Status for Key “k” (0x8k)
This command returns a 1-byte report containing the status for key “k”.
Table 6-8.
Byte 0
Reference for Key “k” Report Format
Bit 7
Bit 6
Bit 5
DETECT
LBL
MBL
Bit 4
Bit 3
DETECT: 0ut of detect, 1 = in detect.
LBL: 0 = lower burst limit is good, 1 = lower burst limit has error.
MBL: 0 = maximum burst limit is good, 1 = maximum burst limit has error. The maximum burst
limit is fixed at 2048 pulses.
AKS_EN: 0 = AKS is disabled, 1 = AKS is enabled.
CAL: 0 = normal, 1 = calibrating.
KEY_EN: 0 = key is disabled, 1 = key is enabled.
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6.11
Detect Output States (0xC6)
This command returns a byte that indicates which PWM signal is applied to each DETECT pin.
Table 6-9.
Reference for Key “k” Report Format
Bit 7
Byte 0
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
DET_6
DET_5
DET_4
DET_3
DET_2
DET_1
DET_0
DET_n: 0 = “Out of Detect” PWM is output, 1 = the “In Detect” PWM is output.
Note:
6.12
Note: During “LED Detect Hold Time” or “LED Fade”, the report indicates the new state
of the DETECT pin. For example, if the DETECT output is in “LED Detect Hold Time”
before switching to “Out of Detect” PWM, the reported state is “0”.
Last Command (0xC7)
This command returns the previous 1-byte command that was received from the host. Note that
this command does not return itself.
Table 6-10.
Reference for Key “k” Report Format
Bit 7
Bit 6
Bit 5
Byte 0
6.13
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Last Command
Setups (0xC8)
This command returns the 42 bytes of the setups table, starting with address 0, with the most
significant bit first.
6.14
Device ID (0xC9)
This command returns 1 byte containing the device ID (0x89).
Table 6-11.
Device ID Report Format
Bit 7
Bit 6
Bit 5
Byte 0
6.15
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
Bit 2
Bit 1
Bit 0
Device ID = 0x89
Firmware Version (0xCA)
Returns 1 byte containing the firmware version.
Table 6-12.
Firmware Version Report Format
Bit 7
Byte 0
Bit 6
Bit 5
Major Version
Bit 4
Bit 3
Minor Version
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7. Setups and Status Information
7.1
Introduction
The bytes of the setup table can be written to or read from individually. The setup table and the
corresponding “Set” and “Get” commands are listed in Table 7-1. Note that there is a
discontinuity in the “Set” and “Get” commands; 0xAF and 0xEF are not implemented.
Table 7-1.
Address
28
Memory Map
Function
Set Command
Get Command
0
Device Mode
0x90
0xD0
1
Guard Key/Comms Options
0x91
0xD1
2
Detect Integrator (DI)/Drift Hold Time (DHT)
0x92
0xD2
3
Positive Threshold (PTHR)/Positive Hysterisis (PHYST)
0x93
0xD3
4
Positive Drift Compensation (PDRIFT)
0x94
0xD4
5
Positive Recalibration Delay (PRD)
0x95
0xD5
6
Lower Burst Limit (LBL)
0x96
0xD6
7
AKS Mask: Keys 8–10
0x97
0xD7
8
AKS Mask: Keys 0–7
0x98
0xD8
9
Detect0 PWM “Detect”/PWM “No Detect”
0x99
0xD9
10
Detect1 PWM “Detect”/PWM “No Detect”
0x9A
0xDA
11
Detect2 PWM “Detect”/PWM “No Detect”
0x9B
0xDB
12
Detect3 PWM “Detect”/PWM “No Detect”
0x9C
0xDC
13
Detect4 PWM “Detect”/PWM “No Detect”
0x9D
0xDD
14
Detect5 PWM “Detect”/PWM “No Detect”
0x9E
0xDE
15
Detect6 PWM “Detect”/PWM “No Detect”
0x9F
0xDF
16
LED Detect Hold Time
0xA0
0xE0
17
LED Fade/Key to LED
0xA1
0xE1
18
LED Latch
0xA2
0xE2
19
Key0 Negative Threshold (NTHR)/Negative Hysterisis (NHYST)
0xA3
0xE3
20
Key1 Negative Threshold (NTHR)/Negative Hysterisis (NHYST)
0xA4
0xE4
21
Key2 Negative Threshold (NTHR)/Negative Hysterisis (NHYST)
0xA5
0xE5
22
Key3 Negative Threshold (NTHR /Negative Hysterisis (NHYST)
0xA6
0xE6
23
Key4 Negative Threshold (NTHR /Negative Hysterisis (NHYST)
0xA7
0xE7
24
Key5 Negative Threshold (NTHR)/Negative Hysterisis (NHYST)
0xA8
0xE8
25
Key6 Negative Threshold (NTHR)/Negative Hysterisis (NHYST)
0xA9
0xE9
26
Key7 Negative Threshold (NTHR)/Negative Hysterisis (NHYST)
0xAA
0xEA
27
Key8 Negative Threshold (NTHR)/Negative Hysterisis (NHYST)
0xAB
0xEB
28
Key9 Negative Threshold (NTHR)/Negative Hysterisis (NHYST)
0xAC
0xEC
29
Key10 NegativeThreshold (NTHR)/Negative Hysterisis (NHYST)
0xAD
0xED
30
Reserved
–
–
31
Key0 Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
0xB0
0xF0
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Table 7-1.
Address
7.2
Memory Map (Continued)
Function
Set Command
Get Command
32
Key1 Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
0xB1
0xF1
33
Key2 Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
0xB2
0xF2
34
Key3 Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
0xB3
0xF3
35
Key4 Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
0xB4
0xF4
36
Key5 Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
0xB5
0xF5
37
Key6 Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
0xB6
0xF6
38
Key7 Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
0xB7
0xF7
39
Key8 Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
0xB8
0xF8
40
Key9 Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
0xB9
0xF9
41
Key10 Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
0xBA
0xFA
Setting Individual Settings
To set up an individual setup value, the host sends the command listed under the “Set
Command” column in Table 7-1, followed by a byte of data.
For details of the communication flow, see Section 4.1 on page 10.
7.3
Setting All the Setups
The host can send all 42 bytes of setup data to the QT1111 as a block using the Send Setups
command. See Section 5.2 on page 22 for details.
7.4
Address 0: Device Mode
The Device Mode controls the overall operation of the device: number of keys, acquisition
method, timing and trigger mechanism.
Table 7-2.
Device Mode
Address
Bit 7
Bit 6
Bit 5
Bit 4
0
KEY_AC
MODE
SIGNAL
SYNC
Bit 3
Bit 2
Bit 1
Bit 0
REPEAT_TIME
KEY_AC: selects the trigger source to start key acquisition; 0 = SYNC pin, 1 = timed.
MODE: selects 7-key or 11-key mode; 0 = default 7-key mode, 1 = 11-key mode.
SIGNAL: selects serial or parallel acquisition of keys signals; 0 = serial, 1 = parallel.
SYNC: selects the trigger type when SYNC Pin is selected as the trigger to start key acquisition.
0 = Level
Acquisition starts when a “0” is read at the SYNC pin. If the pin is held
low, the QT1111 operates in “Free run” mode (that is, it will not sleep in
between acquisitions, but start again immediately).
1 = Edge
Acquisition starts when a rising edge is detected at the SYNC pin.
When acquisition and post-processing are completed, the device
sleeps until another rising edge is detected at the SYNC pin.
29
9571A–AT42–02/10
REPEAT_TIME: selects the “repeat” time when “Timed” is selected as the trigger to start key
acquisition. The number entered is a multiple of 16 ms. If “0” is entered, the device will operate
in a continuous “free run” mode; that is, the QT1111 will not sleep after its cycle is completed but
will begin the next key acquisition cycle immediately.
Default KEY_AC value:
Default MODE value:
Default SIGNAL value:
Default SYNC value:
Default REPEAT_TIME value:
7.5
1 (timed)
0 (7-key mode)
1 (parallel)
1 (edge)
2 (32 ms cycle)
Address 1: Guard Key/Comms Options
Table 7-3.
Address
Guard Key/Comms Options
Bit 7
Bit 6
1
Bit 5
Bit 4
GUARD_KEY
Bit 3
Bit 2
Bit 1
Bit 0
GD_EN
SPI_EN
CHG
CRC
GUARD_KEY: specifies the key (0 to 10) to be used as a guard channel (see Section 2.3 on
page 7) .
GD_EN: enables the use of a guard key; 0 = disable, 1 = enable.
SPI_EN: enables the Quick SPI interface; 0 = disable, 1 = enable (see Table 7-4).
Table 7-4.
Byte
Status Information Bytes
Bit 7
Bit 6
Bit 5
Bit 4
0
Bit 3
Bit 2
Bit 1
Bit 0
Counter
1
Key 3 status
Key 2 status
Key 1 status
Key 0 status
2
Key 7 status
Key 6 status
Key 5 status
Key 4 status
3
Reserved
Key 10 status
Key 9 status
Key 8 status
4
Key 3 error
Key 2 error
Key 1 error
Key 0 error
5
Key 7 error
Key 6 error
Key 5 error
Key 4 error
6
Reserved
Key 10 error
Key 9 error
Key 8 error
See Section 4.1.6 on page 16 for details of the Quick SPI Mode report.
To exit this mode (and clear the “SPI_EN” bit), the command “0x36” should be sent. To save the
settings to EEPROM and make Quick SPI mode active on startup, send the “Store to EEPROM”
command (0x0A). Any other data sent is ignored in Quick SPI mode.
CHG: the CHANGE pin mode (see Section 4.5 on page 17):
0 = “Data” mode. In this mode the “Change” pin is asserted to indicate unread data.
1 = “Touch” mode. In this mode the “Change” pin is asserted when a key is being touched
or is in detect.
CRC: enables or disables CRC; 0 = disable, 1 = enable. When this option is enabled, each data
exchange must have a CRC byte appended.
When report or setup data is being returned by the QT1111, a 1-byte checksum is returned. The
host should confirm that this checksum is correct and, if not, should request the report again.
30
AT42QT1111-MU/AT42QT1111-AU
9571A–AT42–02/10
AT42QT1111-MU/AT42QT1111-AU
Where data is being sent by the host, a 1-byte CRC should be sent. The QT1111 returns the
expected CRC byte in the same transaction the CRC byte is sent. In this way, the host can
immediately determine whether the setup data bytes were received correctly.
Default GUARD_KEY value:
Default GD_EN value:
Default CHG value:
Default CRC value:
7.6
0 (Key 0)
0 (disabled)
0 (data mode)
0 (disabled)
Address 2: Detect Integrator Limit (DIL)/Drift Hold Time (DHT)
Table 7-5.
Address
Detect Integrator/Drift Hold Time
Bit 7
Bit 6
2
Bit 5
Bit 4
Bit 3
Bit 2
DIL
Bit 1
Bit 0
DHT
DIL: the detection integrator (DI) limit. To suppress false detections caused by spurious events
like electrical noise, the device incorporates a DI counter mechanism. A per-key counter is
incremented each time the channel has exceeded its threshold and stayed there for a number of
acquisitions in succession, without going below the threshold level. When this counter reaches a
preset limit the channel is finally declared to be touched. If on any acquisition the delta is not
seen to exceed the threshold level, the counter is cleared and the process has to start from the
beginning.
Note:
A setting of 0 for DI is invalid; the valid range is 1 to 15.
DHT: the drift hold time. After a key-touch has been removed, the QT1111 pauses in the
implementation of its “Drift” compensation for a time. After this time has expired, drift
compensation continues as normal. The “Drift Hold Time” is a multiple of 160 ms, providing
options from 0 to 2400 ms.
Default DIL value:
Default DHT value:
7.7
3
8 (1280 ms)
Address 3: Positive Threshold (PTHR)/Positive Hysteresis (PHYST)
Table 7-6.
Address
3
Positive Threshold (THR)/Positive Hystereis (HYST)
Bit 7
Bit 6
Bit 5
Bit 4
PTHR
Bit 3
Bit 2
Bit 1
Bit 0
PHYST
PTHR: the positive threshold for the signal. If a key signal is significantly higher than the
reference signal, this typically indicates that the calibration data is no longer valid. In other
words, some factor has changed since the calibration was carried out, thus rendering it invalid.
Generally this is compensated for by the drift, but the greater the difference the longer this will
take. In order to speed up this correction, the positive threshold is used: if the positive threshold
is exceeded, the QT1111 (that is, all keys) is recalibrated.
31
9571A–AT42–02/10
PHYST: positive hysteresis. This setting provides a greater degree of control over the
implementation of the positive threshold recalibration. The positive hysteresis operates as a
“modifier” for the positive threshold. When a key signal is detected as being over the positive
threshold, the positive threshold is reduced by a factor corresponding to the positive hysteresis
so that the key will not go in and out of positive detection when the signal is on the borderline
between drift-compensation of a positive error or recalibration.
The settings for positive hysteresis are:
00 = No change to positive threshold
01 = 12.5 percent reduction in positive-detect threshold
10 = 25% reduction in positive-detect threshold
11 = 37.5% reduction in positive-detect threshold
Default PTHR value:
Default PHYST value:
7.8
4 (4 counts above reference)
2 (25% positive hysteresis)
Address 4: Positive Drift Compensation (PDRIFT)
Table 7-7.
Positive Drift Compensation
Address
Bit 7
4
0
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
PDRIFT
When changing ambient conditions cause a change in the key signal, the QT1111 will
compensate through its drift functions. “Positive Drift” refers to the case where the signal for a
key is greater than the reference.
Drift compensation occurs at a rate of 1 count per drift compensation period.
PDRIFT: the drift compensation period, in multiples of 160 ms. The valid range is 0 to 127,
where 0 disables positive drift compensation.
Note:
Drift compensation timing is paused while Drift Hold is activated, and continued when
Drift Hold has timed out.
Default value:
7.9
6 (960 ms)
Address 5: Positive Recalibration Delay (PRD)
Table 7-8.
Address
Positive Recalibration Delay
Bit 7
Bit 6
Bit 5
Bit 4
5
Bit 3
Bit 2
Bit 1
Bit 0
PRD
If a key signal is determined to be above the positive threshold, the QT1111 will wait for this
delay and confirm that the error condition is still present before initiating a recalibration.
PRD: the positive recalibration delay, in multiples of 160 ms.
Note:
All keys are recalibrated in the case of a positive recalibration.
Default value:
32
6 (960 ms)
AT42QT1111-MU/AT42QT1111-AU
9571A–AT42–02/10
AT42QT1111-MU/AT42QT1111-AU
7.10
Address 6: Lower Burst Limit (LBL)
Table 7-9.
Address
Lower Burst Limit
Bit 7
Bit 6
Bit 5
Bit 4
6
Bit 3
Bit 2
Bit 1
Bit 0
LBL
Normal QTouch signals are in the range of 100 to 1000 counts for each key. The lower burst
limit determines the minimum signal that is considered as a valid acquisition. If the count is lower
than the lower burst limit, it is considered not to be valid and the key is set to an Error state.
Note:
Where a key has a signal of less than the LBL, a detection is not reported on that key.
Default value:
7.11
18
Addresses 7–8: AKS Mask
Table 7-10.
Address
AKS Mask
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
7
8
AKS_7
AKS_6
AKS_5
AKS_4
AKS_3
Bit 2
Bit 1
Bit 0
AKS_10
AKS_9
AKS_8
AKS_2
AKS_1
AKS_0
AKS_n (AKS Mask): 0 = key n AKS disabled, 1 = key n AKS enabled (where n is 0–10).
These bits control which keys have AKS enabled (see Section 3 on page 8). A “1” means the
corresponding key has AKS enabled; a “0” means that the corresponding key has AKS disabled.
Default AKS mask:
7.12
0x07 and 0xFF (all keys have AKS enabled)
Addresses 9–15: Detect0 – Detect6 PWM
Each of the 7 detect pins can be configured to output a PWM signal to indicate whether the key
is touched (in detect) or not touched (out of detect).
The Detect outputs must be enabled by selecting 7-key mode in the “Device Mode” setting (see
Section 7.4 on page 29), and the corresponding “Key to LED” bits must be set to enable the
individual “Detect” outputs for each key (see Section 7.14 on page 35).
Table 7-11.
Address
Detect0 – Detect6 PWM
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
9
IN_DETECT0
OUT_DETECT0
10
IN_DETECT1
OUT_DETECT1
11
IN_DETECT2
OUT_DETECT2
12
IN_DETECT3
OUT_DETECT3
13
IN_DETECT4
OUT_DETECT4
14
IN_DETECT5
OUT_DETECT5
15
IN_DETECT6
OUT_DETECT6
Bit 0
IN_DETECTn: PWM to output when key n is “In Detect” (where n is 0–7).
33
9571A–AT42–02/10
OUT_DETECTn: PWM to output when key n is “Out of Detect” (where n is 0–7). This PWM is
also output if the DETECT output is “disconnected” from the key (that is, “LED_n” in address 17
is set to 0), allowing the host to directly control the PWM output.
The values for the “IN_DETECTn” and “OUT_DETECTn” nibbles are listed in Table 7-12.
Table 7-12.
PWM Values
Value
Meaning
0
0%
1
12.5%
2
25%
3
37.5%
4
50%
5
62.5%
6
75%
7
87.5%
8
100%
Default IN_DETECTn value:
Default OUT_DETECTn value:
7.13
8 (100% PWM – on)
0 (0% PWM – off)
Address 16: LED Detect Hold Time
Table 7-13.
Address
LED Detect Hold Time
Bit 7
Bit 6
Bit 5
16
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
LED_DETECT_HOLD_TIME
When a key is touched, if the “Detect” outputs and “Key to LED” options are enabled (see
Section 7.12 and Section 7.14), the corresponding “Detect” pin will output its “In-Detect” PWM
signal.
After the key touch is removed, the “Detect” output can be held at the “In-Detect” PWM signal for
a time before returning to the “Out of Detect” PWM signal. This allows a reasonable length of
time for an LED to be illuminated. The length of this time is controlled by the LED Detect Hold
Time. Valid values are in multiples of 16 ms.
Default value:
34
0 (0 ms)
AT42QT1111-MU/AT42QT1111-AU
9571A–AT42–02/10
AT42QT1111-MU/AT42QT1111-AU
7.14
Address 17: LED Fade/Key to LED
Table 7-14.
LED Fade/Key to LED
Address
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
17
FADE
LED_6
LED_5
LED_4
LED_3
LED_2
LED_1
LED_0
FADE: enables/disables fading for all LEDs. This is a global setting; either all LEDs fade, or
none of them.
0 = disable (no fade).
1 = enable fading on and off.
LED_n: activates the LED output for the corresponding key output DETECTn (where n is 0–6).
1 = enables the “Detect” output to follow the status of the corresponding key.
0 = disable this function, in which case the “Detect” pin will always output its “Out of Detect”
PWM (see Section 7.12 on page 33).
Default FADE value:
Default LED_n value:
7.15
0 (disabled)
1 (enabled)
Address 18: LED Latch
Table 7-15.
LED Latch
Address
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
18
0
LATCH_6
LATCH_5
LATCH_4
LATCH_3
LATCH_2
LATCH_1
LATCH_0
LATCH_n: enables/disables latching of the LED for the corresponding key output DETECTn
(where n is 0–6).
1 = enables latching. When latching is enabled for a given LED, the LED toggles its state each
time the key is touched.
0 = disables latching.
Note that bit 7 is reserved and should be set to zero.
Default LATCH_n value:
7.16
0x00 (latch disabled)
Addresses 19–29: Negative Threshold (NTHR)/Negative Hysteresis (NHYST)
Table 7-16.
Address
Negative Threshold/Negative Hysteresis
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
19
KEY_0_NTHR
KEY_0_NHSYT
20
KEY_1_NTHR
KEY_1_NHSYT
21
KEY_2_NTHR
KEY_2_NHSYT
22
KEY_3_NTHR
KEY_3_NHSYT
23
KEY_4_NTHR
KEY_4_NHSYT
24
KEY_5_NTHR
KEY_5_NHSYT
35
9571A–AT42–02/10
Table 7-16.
Address
Negative Threshold/Negative Hysteresis (Continued)
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
25
KEY_6_NTHR
KEY_6_NHSYT
26
KEY_7_NTHR
KEY_7_NHSYT
27
KEY_8_NTHR
KEY_8_NHSYT
28
KEY_9_NTHR
KEY_9_NHSYT
29
KEY_10_NTHR
KEY_10_NHSYT
KEY_n_NTHR: the negative threshold for key n (where n is 0–10).
The negative threshold determines how much the signal must fall (compared to the reference)
before a key is considered to be “In Detect”. This level will generally need to be tuned
individually for each key. To disable an individual key, set the threshold for that key to 0.
KEY_n_NHYST: the negative hysteresis applied to key n detection threshold (where n is
0 – 10).
Negative Hysteresis operates as a “modifier” for the negative threshold in order to provide a
greater degree of control over the detection of a “Touch”. When a key signal is first detected as
being under the negative threshold, the threshold is reduced by a factor corresponding to the
selected negative hysteresis. This means that the key will not go in and out of detection when
the signal is on the borderline between drift-compensation or touch detection.
The settings for negative hysteresis are:
00
No change to negative threshold
01
12.5% reduction in negative threshold
10
25% reduction in negative threshold
11
37.5% reduction in negative threshold
Default KEY_n_NTHR value:
Default KEY_n_NHYST value:
36
10 counts
2 (25 percent)
AT42QT1111-MU/AT42QT1111-AU
9571A–AT42–02/10
AT42QT1111-MU/AT42QT1111-AU
7.17
Addresses 31–41: Negative Drift Compensation (NDRIFT)/Negative Recalibration Delay (NRD)
Table 7-17.
Address
Negative Drift Compensation/Negative Recalibration Delay
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
31
KEY_0_NDRIFT
KEY_0_NRD
32
KEY_1_NDRIFT
KEY_1_NRD
33
KEY_2_NDRIFT
KEY_2_NRD
34
KEY_3_NDRIFT
KEY_3_NRD
35
KEY_4_NDRIFT
KEY_4_NRD
36
KEY_5_NDRIFT
KEY_5_NRD
37
KEY_6_NDRIFT
KEY_6_NRD
38
KEY_7_NDRIFT
KEY_7_NRD
39
KEY_8_NDRIFT
KEY_8_NRD
40
KEY_9_NDRIFT
KEY_9_NRD
41
KEY_10_NDRIFT
KEY_10_NRD
Bit 0
KEY_n_NDRIFT: the negative drift compensation for key n (where n is 0–10).
When changing ambient conditions cause a change in the key signal, the QT1111 will
compensate through its drift functions. “Negative Drift” refers to the case where the signal for a
key is lower than the reference. Drift compensation occurs at a rate of 1 count per drift
compensation period. The entered number is a multiple of 320 ms.
Note that as a key touch, or an approaching touch, naturally causes a negative change in the
signal, negative drift should be carried out at a much slower rate than positive drift. Otherwise, a
slowly approaching finger will not cause a touch detection, as the falling signal could be
compensated through the negative drift mechanism.
Note:
Drift compensation timing is paused while Drift Hold is activated, and continues when
Drift Hold has timed out.
KEY_n_NRD: the negative recalibration delay for key n (where n is 0–10).
In order to avoid a situation where a key remains “stuck” in detect due to, for example, changing
environmental conditions, the “Negative Recalibration Delay” sets an upper limit on how long a
key can remain “touched”. When this time is exceeded, the QT1111 (that is, all keys) is
recalibrated, taking this key (and any others which are in detect) out of detection. This delay is
set in a multiple of 2560 ms.
Note:
A setting of “0” disables the NRD Timeout.
Default KEY_n_NDRIFT value:
Default KEY_n_NRD value:
7 (2240 ms)
10 (25.6 seconds)
37
9571A–AT42–02/10
8. Specifications
8.1
Absolute Maximum Specifications
Vdd
-0.5 to +6V
Max continuous pin current, any control or drive pin
±10 mA
Voltage forced onto any pin
-1.0V to (Vdd + 0.5) Volts
EEPROM setups maximum writes
100,000 write cycles
CAUTION: Stresses beyond those listed under Absolute Maximum Specifications may cause permanent damage to the
device. This is a stress rating only and functional operation of the device at these or other conditions beyond those indicated
in the operational sections of this specification is not implied. Exposure to absolute maximum specification conditions for
extended periods may affect device reliability
8.2
Recommended Operating Conditions
Operating temperature
-40°C to +°C
Storage temperature
-65°C to +150°C
Vdd
1.8V to 5.5V
Supply ripple + noise
±20 mV
Cx transverse load capacitance per key
2 to 20 pF
8.3
DC Specifications
Vdd = 5.0V, Cs = 4.7 nF, Rs = 1 M, Ta = recommended range, unless otherwise noted
Parameter
Iddr
Average supply current, running
Typ
Max
Units
–
–
12 at 5V
8 at 3V
mA
Notes
For typical values
seeSection 8.8
Low input logic level
-0.5V
–
0.3 Vdd
V
Vih
High input logic level
0.6 Vdd
Vdd
Vdd + 0.5V
V
Vol
Low output voltage
0
–
0.7
V
10 mA sink current
Voh
High output voltage
0.8 Vdd
–
Vdd
V
10 mA source current
Input leakage current
–
<0.05
1
µA
Internal RST pull-up resistor
30
–
60
k
Min
Typ
Max
Units
Rrst
Timing Specifications
Parameter
38
Min
Vil
Iil
8.4
Description
Description
TBS
Burst duration
–
6
–
ms
Fc
Burst center frequency
–
40
–
kHz
Fm
Burst modulation, percentage
–
18
–
%
TPW
Pulse width
–
9000
–
µs
Notes
4.7 nF Cs/parallel acquisition
AT42QT1111-MU/AT42QT1111-AU
9571A–AT42–02/10
AT42QT1111-MU/AT42QT1111-AU
8.5
SPI Bus Specifications
8.5.1
General Specifications
Parameter
Specification
Address space
8-bit
Maximum clock rate
750 KHz
Minimum low clock period
666 ns
Minimum high clock period
666 ns
Clock idle
High
Setup on
Leading (falling) edge
Clock out on
Trailing (rising) edge
SPI Enable delay (SS low to SCK low)
1 µs
8.5.2
Full SPI Mode
Parameter
Specification
Time between bytes
300 µs
Generally 300 µs; longer delays required to implement some commands, as follows:
• Send Setups: 300 µs after all setup bytes are returned
• Calibrate All: 300 µs
• Calibrate Key: 300 µs
Time between communications
• Reset: 320 ms
• Sleep: 300 µs after a low signal is applied to SS or CHANGE to wake the device
• Store to EEPROM: 200 ms
• Restore from EEPROM: 150 ms
• Erase EEPROM: 50 ms
• Recover EEPROM: 50 ms
8.5.3
Quick SPI Mode
Parameter
Specification
Time between bytes
100 µs
Generally 100 µs, except for the following:
Time between communications
• Store to EEPROM: 200 ms
• Switch to Full SPI: 300 µs
39
9571A–AT42–02/10
Figure 8-1.
Signals on SPI Pins During the Exchange of a Data Byte
SCK
SAMPLE
MOSI/MISO
CHANGE
MOSI PIN
CHANGE
MISO PIN
SS
MSB
8.6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Description
Operation
VRST
Threshold voltage low (Activate)
Threshold voltage high (Release)
0.2Vdd
0.9Vdd
Reset
Minimum length of Reset low
600 ns at 5V
1100 ns at 3V
Internal Resonator
Parameter
Operation
Internal RC oscillator
8 MHz with spread-spectrum modifier during measurement bursts
40
LSB
External Reset
Parameter
8.7
Bit 6
AT42QT1111-MU/AT42QT1111-AU
9571A–AT42–02/10
9571A–AT42–01/10
Note:
5.0V
3.0V
1.0V
Vdd (V)
Note:
5.0V
3.0V
3125
2320
34.8ms
68.4ms
135ms
254ms
22.2ms
22.2ms
34.6ms
67.6ms
134ms
250ms
26.2ms
26.2ms
34.4ms
66.8ms
132ms
2 (32 ms Nominal)
4 (64 ms Nominal)
8 (128 ms Nominal)
15 (240 ms Nominal)
0 (Free Run)
1 (16 ms Nominal)
2 (32 ms Nominal)
4 (64 ms Nominal)
8 (128 ms Nominal)
15 (240 ms Nominal)
0 (Free Run)
1 (16 ms Nominal)
2 (32 ms Nominal)
4 (64 ms Nominal)
8 (128 ms Nominal)
11-key Serial
11-key Serial, 1 key enabled
990
990
990
990
990
990
990
990
990
1435
1435
1435
320
370
465
645
770
770
248ms
132ms
67.2ms
34.2ms
26ms
26ms
250ms
133ms
67.6ms
34.6ms
22.2ms
22.2ms
254ms
136ms
68.4ms
34.8ms
17.9ms
15.8ms
1640
1920
2430
3450
4080
4080
520
605
790
1135
1530
1530
295
315
380
495
730
790
11-key Parallel
10 nF Cs Capacitors
7-key Serial
246ms
133ms
68ms
43.2ms
43.2ms
43.2ms
250ms
135ms
68.8ms
37.4ms
37.4ms
37.4ms
254ms
135ms
69.2ms
35.4ms
27ms
27ms
325
390
520
770
770
770
1850
2275
3115
3180
3180
3180
630
800
1160
1480
1480
1480
11-key Serial
250
134ms
69.2ms
58.8ms
58.8ms
58.8ms
350ms
136ms
69.6ms
49.2ms
49.2ms
49.2ms
254ms
137ms
69.6ms
36ms
36ms
36ms
4.4ms
1425
1460
1530
1705
2135
3425
450
470
505
590
750
1260
260
270
285
315
380
745
11-key Serial, 1 key enabled
244ms
130ms
65.6ms
33ms
16.6ms
6.48ms
248ms
132ms
66.4ms
33.4ms
16.8ms
6.5ms
252ms
135ms
67.6ms
33.8ms
16.9ms
595
440
320
1436
645
4315
34.4 ms
66.8 ms
131 ms
246 ms
24.2 ms
24.2 ms
34.4 ms
66.8 ms
131 ms
246 ms
26 ms
26 ms
34 ms
66 ms
131 ms
2 (32 ms Nominal)
4 (64 ms Nominal)
8 (128 ms Nominal)
15 (240 ms Nominal)
0 (Free Run)
1 (16 ms Nominal)
2 (32 ms Nominal)
4 (64 ms Nominal)
8 (128 ms Nominal)
15 (240 ms Nominal)
0 (Free Run)
1 (16 ms Nominal)
2 (32 ms Nominal)
4 (64 ms Nominal)
8 (128 ms Nominal)
15 (240 ms Nominal)
244 ms
2405
These values are for reference only; values are untested.
2740
3410
4315
4315
775
970
1390
1436
355
775
24.2 ms
775
24.2 ms
0 (Free Run)
1 (16 ms Nominal)
244 ms
132 ms
67.6 ms
56.4 ms
56.4 ms
56.4 ms
248 ms
133 ms
68.4 ms
48.4 ms
48.4 ms
48.4 ms
248 ms
133 ms
68.4 ms
48.4 ms
48.4 ms
48.4 ms
2730
3205
4180
4180
4180
4180
780
990
1335
1470
1470
1470
360
430
585
805
805
805
242 ms
130 ms
66.4 ms
34 ms
28 ms
28 ms
246 ms
132 ms
66.4 ms
34 ms
24.2 ms
24.2 ms
246 ms
132 ms
66.4 ms
34 ms
24.2 ms
24.2 ms
1520
2550
3230
4470
4470
4470
565
680
1035
1430
1475
1475
300
345
430
600
790
790
246 ms
133 ms
73.6 ms
73.6 ms
73.6 ms
73.6 ms
248 ms
134 ms
69.6 ms
63.6 ms
63.6 ms
63.6 ms
248 ms
134 ms
69.6 ms
63.6 ms
63.6 ms
63.6 ms
2575
3040
3900
3900
3900
3900
810
1030
1440
1440
1440
1440
370
470
675
785
785
785
241 ms
129 ms
64.8 ms
32.6 ms
16.6 ms
8.6 ms
243 ms
130 ms
65 ms
33 ms
16.7 ms
8.6 ms
243 ms
130 ms
65 ms
33 ms
16.7 ms
8.6 ms
2075
2180
2345
2755
3345
4140
530
570
635
785
1040
1320
265
280
305
360
460
785
Actual Cycle Time Idd (µA) Actual Cycle Time Idd (µA) Actual Cycle Time Idd (µA) Actual Cycle Time Idd (µA) Actual Cycle Time Idd (µA)
7-key Parallel
15 (240 ms Nominal)
246ms
1690
These values are for reference only; values are untested.
1890
3680
3680
545
625
785
1120
1450
1450
305
330
390
510
710
17.8ms
770
15.8ms
0 (Free Run)
Cycle Time
11-key Parallel
Actual Cycle Time Idd (µA) Actual Cycle Time Idd (µA) Actual Cycle Time Idd (µA) Actual Cycle Time Idd (µA) Actual Cycle Time Idd (µA)
1 (16 ms Nominal)
Cycle Time
4.7 nF Cs Capacitors
7-key Serial
8.8
1.0V
Vdd (V)
7-key Parallel
AT42QT1111-MU/AT42QT1111-AU
Power Consumption
41
8.9
Mechanical Dimensions
8.9.1
AT42QT1111-MU – 32-pin 5 x 5 mm MLF
D
D1
1
2
3
0
Pin 1 ID
E1
SIDE VIEW
E
TOP VIEW
A3
A2
A1
A
K
0.08 C
COMMON DIMENSIONS
(Unit of Measure = mm)
SYMBOL
MIN
A
0.80
0.90
1.00
A1
–
0.02
0.05
A2
–
0.65
1.00
P
D2
1
2
3
P
Pin #1 Notch
(0.20 R)
A3
E2
K
e
b
L
BOTTOM VIEW
MAX
NOTE
0.20 REF
b
0.18
0.23
D
4.90
5.00
5.10
D1
4.70
4.75
4.80
D2
2.95
3.10
3.25
E
4.90
5.00
5.10
E1
4.70
4.75
4.80
E2
2.95
3.10
3.25
e
Note: JEDEC Standard MO-220, Fig. 2 (Anvil Singulation), VHHD-2.
NOM
0.30
0.50 BSC
L
0.30
0.40
0.50
0.60
12o
P
–
–
0
–
–
K
0.20
–
–
5/25/06
R
42
2325 Orchard Parkway
San Jose, CA 95131
TITLE
32M1-A, 32-pad, 5 x 5 x 1.0 mm Body, Lead Pitch 0.50 mm,
3.10 mm Exposed Pad, Micro Lead Frame Package (MLF)
DRAWING NO.
32M1-A
REV.
E
AT42QT1111-MU/AT42QT1111-AU
9571A–AT42–02/10
AT42QT1111-MU/AT42QT1111-AU
8.9.2
AT42QT1111-AU – 32-pin 7 x 7 mm TQFP
PIN 1
B
PIN 1 IDENTIFIER
E1
e
E
D1
D
C
0˚~7˚
A1
A2
A
L
COMMON DIMENSIONS
(Unit of Measure = mm)
MIN
NOM
MAX
A
–
–
1.20
A1
0.05
–
0.15
A2
0.95
1.00
1.05
D
8.75
9.00
9.25
D1
6.90
7.00
7.10
E
8.75
9.00
9.25
E1
6.90
7.00
7.10
B
0.30
–
0.45
C
0.09
–
0.20
L
0.45
–
0.75
SYMBOL
Notes:
1. This package conforms to JEDEC reference MS-026, Variation ABA.
2. Dimensions D1 and E1 do not include mold protrusion. Allowable
protrusion is 0.25 mm per side. Dimensions D1 and E1 are maximum
plastic body size dimensions including mold mismatch.
3. Lead coplanarity is 0.10 mm maximum.
e
NOTE
Note 2
Note 2
0.80 TYP
10/5/2001
R
2325 Orchard Parkway
San Jose, CA 95131
TITLE
32A, 32-lead, 7 x 7 mm Body Size, 1.0 mm Body Thickness,
0.8 mm Lead Pitch, Thin Profile Plastic Quad Flat Package (TQFP)
DRAWING NO.
REV.
32A
B
43
9571A–AT42–02/10
8.10
8.10.1
Marking
AT42QT1111-MU – 32-pin 5 x 5 mm MLF
5 x 5 mm MLF
Either of the following markings may be used.
Pin 1 ID
Abbreviation of
Part Number:
32
1
1111
AT42QT1111 -MU
1R0
Program week code number 1-52
where:
A = 1, B = 2...Z = 26
then using the underscore
A = 27...Z = 52
Code revision:
1.0 Released
Pin 1 ID
32
1
Abbreviation of
Part Number:
AT42QT1111 - MU
Datecode/
Lot Number
44
ATMEL
QT1111
MU 1R0
Date code Country Code
Code Revision:
1.0, Released
Lot number
AT42QT1111-MU/AT42QT1111-AU
9571A–AT42–02/10
AT42QT1111-MU/AT42QT1111-AU
8.10.2
AT42QT1111-AU – 32-pin 7 x 7 mm TQFP
Either of the following markings may be used.
32
Pin 1 ID
1
Abbreviation of
Part Number:
QT1111
AU 1R0
AT42QT1111 - AU
Code Revision:
1.0, Released
Program week code number 1-52
where:
A = 1, B = 2...Z = 26
then using the underscore
A = 27...Z = 52
32
Pin 1 ID
1
Abbreviation of
Part Number:
AT42QT1111 - AU
Datecode/
Lot Number
ATMEL
QT1111
AU 1R0
DATE/LOT
Code Revision:
1.0, Released
45
9571A–AT42–02/10
8.11
Part Number
Part Number
8.12
46
Description
AT42QT1111-MU
32-pin 5 x 5 mm MLF RoHS compliant (-40°C to +85°C)
AT42QT1111-AU
32-pin 7 x 7 mm TQFP RoHS compliant (-40°C to +85°C)
Moisture Sensitivity Level (MSL)
MSL Rating
Peak Body Temperature
Specifications
MSL3
260oC
IPC/JEDEC J-STD-020
AT42QT1111-MU/AT42QT1111-AU
9571A–AT42–02/10
AT42QT1111-MU/AT42QT1111-AU
Appendix A.
CRC Calculation
If the use of a cyclic redundancy check (CRC) during data transmission is enabled, the host
must generate a valid CRC so that this can be correctly compared to the corresponding CRC
generated by the QT1111. This appendix gives example C code to show how the CRC can be
generated by the host.
/*=======================================================================
unsigned char calc_crc(unsigned char crc, unsigned char data)
--------------------------------------------------------------------------Purpose: Calculate CRC for data packets
Input : CRC, Data
Output : Updated CRC
Notes : =========================================================================*/
unsigned char calc_crc(unsigned char crc, unsigned char data)
{
unsigned char index;
unsigned char fb;
index = 8;
do
{
fb = (crc ^ data) & 0x01u;
data >>= 1u;
crc >>= 1u;
if(fb)
{
crc ^= 0x8c;
}
} while(--index);
return crc;
}
/* Example Calling Routine */
unsigned char calculate_config_checksum(void)
{
int i;
unsigned char CRC_val = 0;
unsigned char setup_data[42] =
{
0xB2, 0x00, 0x38, 0x12, 0x06, 0x06, 0x12, 0x07, 0xFF, 0x80,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x32, 0xFF, 0x00, 0x29,
0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80, 0x80,
0X00, 0x7A, 0x7A, 0x7A, 0x7A, 0x7A, 0x7A, 0x7A, 0x7A, 0x7A,
0x7A, 0x7A
};
for(i = 0; i < sizeof(setup_data); i++)
{
CRC_val = calc_crc(CRC_val, setup_data[i]);
}
return(CRC_val);
}
47
9571A–AT42–02/10
Revision History
48
Revision No.
History
Revision A – February 2010

Initial Release for chip revision 1.0
AT42QT1111-MU/AT42QT1111-AU
9571A–AT42–02/10
AT42QT1111-MU/AT42QT1111-AU
Notes
49
9571A–AT42–02/10
Headquarters
International
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Tel: 1(408) 441-0311
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Product Contact
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Literature Requests
www.atmel.com/literature
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9571A–AT42–02/10