QT1101-ISG [QUANTUM]
10 KEY QTOUCH SENSOR IC; 10键的QTouch传感器IC
| 型号: | QT1101-ISG |
| 厂家: | 
QUANTUM RESEARCH GROUP |
| 描述: | 10 KEY QTOUCH SENSOR IC |
| 文件: | 总16页 (文件大小:234K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
lQ
QT1101
10 KEY QTOUCH™ SENSOR IC
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Patented charge-transfer (‘QT’) design
Ten independent QT sensing fields (keys)
2.8V ~ 5.5V single supply operation
24 23 22
20 19 18 17
21
40µA current typ @ 3V in 360ms LP mode
100% autocal for life - no adjustments required
Serial one or two wire interface with auto baud rate
Fully debounced results
SNS8
SNS8K
SNS9
SNS5
25
26
27
28
29
30
31
32
16
15
14
13
12
11
10
9
SNS4K
SNS4
SNS9K
N.C.
SNS3K
SNS3
QT1101
32-QFN
Patented AKS™ Adjacent Key Suppression
Spread spectrum bursts for superior noise rejection
Sync pin for excellent LF noise rejection
‘Fast mode’ for use in slider type applications
RoHS compliant 32-QFN, 48-SSOP packages
/CHANGE
1W
SNS2K
SNS2
RX
SNS1K
1
2
3
5
6
7
8
4
APPLICATIONS
! MP3 players
! Mobile phones
! PC peripherals
! Television controls
! Pointing devices
! Remote controls
QT1101 charge-transfer (‘QT’) QTouchTM IC is a self-contained, patented digital controller capable of detecting near-proximity or touch
on up to ten electrodes. It allows electrodes to project independent sense fields through any dielectric such as glass or plastic. This
capability coupled with its continuous self-calibration feature can lead to entirely new product concepts, adding high value to product
designs. The devices are designed specifically for human interfaces, like control panels, appliances, gaming devices, lighting controls,
or anywhere a mechanical switch or button may be found; they may also be used for some material sensing and control applications.
Each of the channels operates independently of the others, and each can be tuned for a unique sensitivity level by simply changing a
corresponding external Cs capacitor.
Patented AKS™ Adjacent Key Suppression suppresses touch from weaker responding keys and allows only a dominant key to detect,
for example to solve the problem of large fingers on tightly spaced keys.
Spread spectrum burst technology provides superior noise rejection. These devices also have a SYNC/LP pin which allows for
synchronization with additional similar parts and/or to an external source to suppress interference, or, an LP (low power) mode which
conserves power.
By using the charge transfer principle, this device delivers a level of performance clearly superior to older technologies yet is highly
cost-effective.
AVAILABLE OPTIONS
TA
32-QFN
QT1101-ISG
48-SSOP
QT1101-IS48G
-400C to +850C
LQ
C
Copyright © 2005-2006 QRG Ltd
QT1101 R4.06/0806
Spread Spectrum operation: The bursts operate over a
spread of frequencies, so that external fields will have
minimal effect on key operation and emissions are very
weak. Spread spectrum operation works with the DI
mechanism to dramatically reduce the probability of false
detection due to noise.
1 Overview
The QT1101 is an easy to use, ten touch-key sensor IC
based on Quantum’s patented charge-transfer (‘QT’)
principles for robust operation and ease of design. This
device has many advanced features which provide for
reliable, trouble-free operation over the life of the product.
Sync Mode: The QT1101 features a Sync mode to allow the
device to slave to an external signal source, such as a mains
signal (50/60Hz), to limit interference effects. This is
performed using the SYNC/LP pin. Sync mode operates by
triggering three sequential acquire bursts, in sequence
A-B-C from the Sync signal. Thus, each Sync pulse causes
all ten keys to be acquired.
Burst operation: The device operates in ‘burst mode’. Each
key is acquired using a burst of charge-transfer sensing
pulses whose count varies depending on the value of the
reference capacitor Cs and the load capacitance Cx. In LP
mode, the device sleeps in an ultra-low current state
between bursts to conserve power. The keys signals are
acquired using three successive bursts of pulses:
Low Power (LP) Mode: The device features an LP mode for
microamp levels of current drain with a slower response
time, to allow use in battery operated devices. On detection
of touch, the device automatically reverts to its normal mode
and asserts the DETECT pin active to wake up a host
controller. The device remains in normal, full acquire speed
mode until another pulse is seen on its SYNC/LP pin, upon
which it goes back to LP mode.
Burst A: Keys 0, 1, 4, 5
Burst B: Keys 2, 3, 6, 7
Burst C: Keys 8, 9
Bursts always operate in A-B-C sequence.
Self-calibration: On power-up, all ten keys are
self-calibrated within 450ms typical to provide reliable
operation under almost any conditions.
AKS™ Adjacent Key Suppression is a patented feature
that can be enabled via jumper resistors. AKS works to
prevent multiple keys from responding to a single touch, a
common complaint about capacitive touch panels. This can
happen with closely spaced keys, or with control surfaces
that have water films on them.
Auto-recalibration: The device can time out and recalibrate
each key independently after a fixed interval of continuous
touch detection, so that the keys can never become ‘stuck
on’ due to foreign objects or other sudden influences. After
recalibration the key will continue to function normally. The
delay is selectable to be either 10s, 60s, or infinite
(disabled).
AKS operates by comparing signal strengths from keys
within a group of keys to suppress touch detections from
those that have a weaker signal change than the dominant
one.
The device also auto-recalibrates a key when its signal
reflects a sufficient decrease in capacitance. I n this case the
device recalibrates after ~2 seconds so as to recover normal
operation quickly.
The QT1101 has two different AKS groupings of keys,
selectable via option resistors. These groupings are:
Drift compensation operates to correct the reference level
of each key slowly but automatically over time, to suppress
false detections caused by changes in temperature,
humidity, dirt and other environmental effects.
AKS operates in three groups of keys.
AKS operates over all ten keys.
These two modes allow the designer to provide AKS while
also providing for shift or function operations.
The drift compensation is asymmetric. In the increasing
capacitive load direction the device drifts more slowly than in
the decreasing direction. In the increasing direction, the rate
of compensation is one count of signal per two seconds. In
the opposing direction, it is one count every 500ms.
If AKS is disabled, all keys can operate simultaneously.
Outputs: The QT1101 has a serial output using one or two
wires, RS-232 data format, and automatic baud rate
detection. A simple protocol is employed.
Detection Integrator (DI) confirmation reduces the effects
of noise on the QT1101 outputs. The DI mechanism requires
consecutive detections over a number of measurement
bursts for a touch to be confirmed and indicated on the
outputs. In a like manner, the end of a touch (loss of signal)
has to be confirmed over a number of measurement bursts.
This process acts as a type of ‘debounce’ against noise.
The QT1101 operates in slave mode, i.e. it only sends data
to the host after receiving a request from the host.
An additional /CHANGE (state changed) signal allows the
use of the serial interface to be optimised, rather than being
polled continuously.
Simplified Mode: To reduce the need for option resistors,
the simplified operating mode places the part into fixed
settings with only the AKS feature being selectable. LP
mode is also possible in this configuration. Simplified mode
is suitable for most applications.
In normal operation, both the start and end of a touch must
be confirmed for six measurement bursts. In a special ‘Fast
Detect‘ mode (available via jumper resistors) (Tables 1.2 and
1.6), confirmation of the start of a touch requires only two
sequential detections, but confirmation of the end of a touch
is still six bursts.
Fast detect is only available when AKS is disabled.
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QT1101 R4.06/0806
1.1 Wiring
Table 1.1 Pinlist
Function
32-QFN 48 SSOP
Name
Type
Notes
If Unused
Pin
Pin
1
-
2
3
33
34
35
36
SS
n/c
/RST
Vdd
OD
-
I
Spread spectrum
Spread spectrum drive
-
100K✡ resistor to Vss
-
Open
Vdd
-
Reset input
Power
Active low reset
+2.8 ~ +5.0V
Pwr
Resistor to Vdd and optional
spread spectrum RC network
Leave open
4
5
-
37
OSC
n/c
I
-
-
Oscillator
-
-
38
39, 40,
41, 42
-
-
n/c
-
Open
Sense pin and
option select
Sense pin
Sense pin and
option select
Sense pin
Sense pin and
option select
Sense pin
Sense pin and
option select
Sense pin
To Cs0 and/or
option resistor
To Cs0 + Key
To Cs1 and/or
option resistor*
To Cs1 + Key
To Cs2 and/or
option resistor*
To Cs2 + Key
To Cs3 and/or
option resistor*
To Cs3 + Key
To Cs4
Open or
option resistor*
Open
Open or
option resistor*
Open
Open or
option resistor*
6
7
43
44
45
46
47
48
1
SNS0
SNS0K
SNS1
I/O
I/O
I/O
I/O
I/O
I/O
I/O
8
9
SNS1K
SNS2
10
11
12
SNS2K
SNS3
Open
Open or
option resistor*
13
14
15
2
3
4
SNS3K
SNS4
SNS4K
I/O
I/O
I/O
Open
Open
Open
Open or
Sense pin
Sense pin
To Cs4 + Key
To Cs5 and/or
option resistor *
To Cs5 + Key
To Cs6 and/or
option resistor*
To Cs6 + Key and/or
mode resistor†
Sense pin and
option select
Sense pin
Sense pin and
option select
Sense pin and
mode select
16
17
18
5
6
7
SNS5
SNS5K
SNS6
I/O
I/O
I/O
option resistor*
Open
Open or
option resistor*
Open or
19
20
8
9
SNS6K
SNS7
I/O
I/O
mode resistor†
Open or mode
resistor† or option
resistor*
Sense pin and mode
or option select
To Cs7 and/or mode resistor†
or option resistor*
21
-
10
SNS7K
n/c
I/O
-
Sense pin
-
To Cs7 + Key
-
Open
11, 12, 13,
14, 15, 16
Open
22
-
23
24
-
25
26
27
28
29
17
18, 19, 20
21
22
23, 24
25
Vss
n/c
Pwr
-
I
O/OD
-
I/O
I/O
I/O
I/O
-
Ground
-
Sync In or LP In
Detect Status
-
0V
-
Open
Vdd or Vss**
Open
-
Rising edge sync or LP pulse
See Table 1.4
-
SYNC/LP‡
DETECT
n/c
Open
Open
Open
Open
Open
Open
SNS8
SNS8K
SNS9
SNS9K
n/c
Sense pin
Sense pin
Sense pin
Sense pin
-
To Cs8
To Cs8 + Key
To Cs9
To Cs9 + Key
-
26
27
28
29
0 = a key state has changed
Requires pull-up
Requires pull-up to Vdd
Input for 2W mode
30
30
/CHANGE
OD
State changed
100K✡ resistor to Vss
31
32
31
32
1W
RX
I/OD
I
1W mode serial I/O
2W Receive
-
Vdd
Pin Type
I
CMOS input only
CMOS I/O
I/O
OD
CMOS open drain output
I/OD
O/OD
Pwr
CMOS input or open drain output
CMOS push pull or open-drain output (option selected)
Power / ground
Notes
† Mode resistor is required only in Simplified mode (see Figure 1.2)
* Option resistor is required only in Full Options mode (see Figure 1.1)
‡ Pin is either Sync or LP depending on options selected (functions SL_0, SL_1, see Figure 1.1)
** See text
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QT1101 R4.06/0806
Figure 1.1 Connection Diagram - Full Options (32-QFN Package)
VDD
+2.8 ~ +5V
Voltage Reg
Vunreg
4.7uF
4.7uF
*100nF
3
2
RSNS2
2.2K
VDD
/RST
4.7nF
11
10
9
12
13
SNS2K
SNS2
SNS3
KEY 2
KEY 1
KEY 0
MOD_0
Vdd / Vss
1M
1M
1M
RSNS3
MOD_1
Vdd / Vss
RS2
4.7nF
CS3
RS3
10K
1M
CS2
4.7nF
CS1
4.7nF
SNS3K
SNS4
KEY 3
KEY 4
KEY 5
KEY 6
KEY 7
KEY 8
KEY 9
RSNS1
2.2K
2.2K
RS1
10K
SNS1K
SNS1
AKS_1
Vdd / Vss
RSNS4
4.7nF
4.7nF
4.7nF
RS4
10K
CS4
8
15
16
17
18
19
20
21
25
26
27
28
SNS4K
SNS5
RSNS0
2.2K
2.2K
RS0
10K
7
SNS0K
SNS0
AKS_0
Vdd / Vss
OUT_D
Vdd / Vss
RSNS5
CS5
RS5
10K
1M
1M
1M
6
CS0
SNS5K
SNS6
2.2K
2.2K
10K
VDD
RSNS6
SL_0
Vdd / Vss
Recommended Rb1, Rb2 Values
CS6
RS6
QT1101
32-QFN
SNS6K
SNS7
With Spread-Spectrum
Vdd Range
2.8 ~ 2.99V 12K 27K
3.0 ~ 3.59V 12K 22K
3.6 ~ 5V 15K 27K
2.2K
10K
Rb1 Rb2
Rb1
Rb2
RSNS7 4.7nF
SL_1
Vdd / Vss
RS7
CS7
SNS7K
SNS8
4
2.2K
OSC
10K
RSNS8
4.7nF
CS8
RS8
No Spread-Spectrum
Vdd Range
2.8 ~ 2.99V 15K
3.0 ~ 3.59V 18K
3.6 ~ 5V 20K
SNS8K
SNS9
Rb1 Rb2
2.2K
10K
dni
dni
dni
RSNS9 4.7nF
RS9
CS9
Css
SNS9K
1
SS
10K
100nF
dni = do not install
No Spread-spectrum:
Replace Css with 100K resistor
100K
Vdd
32
31
30
29
RX
1W
2W DATA
DATA
100K
100K
23
Vdd
Vdd
SYNC or LP
SYNC/LP
DETECT
Pullup not required for push-pull mode
See Detect pin mode table below
/CHANGE
N.C.
/CHANGE
100K
Vdd
24
DETECT OUT
5
N.C.
VSS
22
Table 1.2
AKS / Fast-Detect Options
AKS_1
Vss
Vss
Vdd
Vdd
AKS_0
Vss
Vdd
Vss
Vdd
AKS MODE
Off
Off
On, in 3 groups
On, global
FAST-DETECT
Off
Enabled
Off
Off
Table 1.3
Max On-Duration
MOD_1
Vss
Vss
MOD_0
Vss
Vdd
MAX ON-DURATION MODE
10 seconds to recalibrate
60 seconds to recalibrate
Infinite (disabled)
Vdd
Vss
Vdd
Vdd
(reserved)
Table 1.4
Detect Pin Drive
OUT_D
Vss
Vdd
DETECT PIN MODE
Open drain, active low
Push-pull, active high
Table 1.5
SYNC/LP Function
SL_1
Vss
Vss
Vdd
Vdd
SL_0
Vss
Vdd
Vss
SYNC/LP PIN MODE
Sync
LP mode: 120ms response time
LP mode: 200ms response time
LP mode: 360ms response time
Vdd
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QT1101 R4.06/0806
Figure 1.2 Connection Diagram - Simplified Mode (32-QFN Package)
SMR resistor installed between SNS6K, SNS7
VDD
+2.8 ~ +5V
Voltage Reg
Vunreg
4.7uF
4.7uF
*100nF
3
2
RSNS2
RS3
RS4
RS5
VDD
/RST
4.7nF
11
10
9
12
13
SNS2K
SNS2
SNS3
KEY 2
KEY 1
KEY 0
4.7nF
RSNS3
RS2
CS3
2.2K
2.2K
10K
CS2
4.7nF
CS1
4.7nF
SNS3K
SNS4
KEY 3
KEY 4
KEY 5
KEY 6
KEY 7
KEY 8
KEY 9
RSNS1
10K
2.2K
RS1
SNS1K
SNS1
RSNS4
4.7nF
4.7nF
4.7nF
10K
CS4
8
15
16
17
18
19
20
21
25
26
27
28
SNS4K
SNS5
RSNS0
2.2K
RS0
10K
7
SNS0K
SNS0
AKS_0
Vdd / Vss
RSNS5
1M
CS5
10K
2.2K
6
CS0
SNS5K
SNS6
RS6
10K
2.2K
VDD
RSNS6
CS6
2.2K
SMR
Recommended Rb1, Rb2 Values
QT1101
32-QFN
SNS6K
SNS7
RS7
10K
With Spread-Spectrum
Vdd Range
2.8 ~ 2.99V 12K 27K
3.0 ~ 3.59V 12K 22K
3.6 ~ 5V 15K 27K
1M
Rb1 Rb2
Rb1
Rb2
RSNS7 4.7nF
2.2K
2.2K
2.2K
CS7
SNS7K
SNS8
4
RS8
OSC
10K
RSNS8
4.7nF
CS8
SNS8K
SNS9
No Spread-Spectrum
Vdd Range
2.8 ~ 2.99V 15K
3.0 ~ 3.59V 18K
3.6 ~ 5V 20K
RS9
10K
Rb1 Rb2
dni
dni
dni
RSNS9 4.7nF
CS9
Css
SNS9K
1
SS
10K
100nF
No Spread-spectrum:
dni = do not install
Replace Css with 100K resistor
100K
100K
100K
Vdd
Vdd
Vdd
32
31
30
29
RX
1W
2W DATA
DATA
23
LP IN
SYNC/LP
DETECT
/CHANGE
N.C.
/CHANGE
24
DETECT OUT
5
N.C.
VSS
22
Table 1.6
AKS Resistor Options
AKS_0
Vss
Vdd
AKS MODE
Off
On, global
FAST-DETECT
Enabled
Off
Table 1.7
Functions in Simplified Mode
SYNC/LP pin
200ms LP function; sync not available
60 seconds
Max on-duration delay
Detect Pin
Push-pull, active high
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QT1101 R4.06/0806
A trigger pulse on SYNC will cause the device to fire three
acquire bursts in A-B-C sequence:
2 Device Operation
Burst A: Keys 0, 1, 4, 5
Burst B: Keys 2, 3, 6, 7
Burst C: Keys 8, 9
2.1 Startup Time
After a reset or power-up event, the device requires 450ms
to initialize, calibrate, and start operating normally. Keys will
work properly once all keys have been calibrated after reset.
Low Power (LP) Mode: This allows the device to enter a
slow mode with very low power consumption, in one of three
response time settings - 120ms, 200ms, and 360ms
nominal.
2.2 Option Resistors
The option resistors are read on power-up only. There are
two primary option mode configurations: full, and simplified.
LP mode is entered by a positive pulse on the SYNC/LP pin.
Once the LP pulse is detected, the device will enter and
remain in this microamp mode until it senses and confirms a
touch, upon which it will switch back to normal (full speed)
mode on its own, with a response time of <40ms typical
(burst length dependent). The device will go back to LP
mode again if SYNC/LP is held high or after another LP
pulse is received.
In full options mode, seven 1M✡ option resistors are
required as shown in Figure 1.1. All seven resistors are
mandatory.
To obtain simplified mode, a 1M✡ resistor should be
connected from SNS6K to SNS7. In simplified mode, only
one additional 1M✡ option resistor is required for the AKS
feature (Figure 1.2).
The response time setting is determined by option resistors
SL_1 and SL_0 (see Table 1.5). Slower response times
result in lower power drain.
Note that the presence and connection of option resistors
will influence the required values of Cs; this effect will be
especially noticeable if the Cs values are under 22nF. Cs
values should be adjusted for optimal sensitivity after the
option resistors are connected.
The SYNC/LP pulse should be >150µs in duration.
If the SYNC/LP pin is held high permanently, the device will
go into normal mode during a key touch, and return to
low-current mode after the detection has ceased and the key
state has been read by the host.
2.3 DETECT Pin
DETECT represents the functional logical-OR of all ten keys.
DETECT can be used to wake up a battery-operated product
upon human touch.
If the SYNC/LP pin is held low constantly, the device will
remain in normal full speed mode continuously.
The output polarity and drive of DETECT are governed
according to Table 1.4, page 4.
2.6 AKS™ Function Pins
The QT1101 features an adjacent key suppression (AKS™)
function with two modes. Option resistors act to set this
feature according to Tables 1.2 and 1.6. AKS can be
disabled, allowing any combination of keys to become active
at the same time. When operating, the modes are:
2.4 /CHANGE Pin
The /CHANGE pin can be used to tell the host that a change
in touch state has been detected (i.e. a key has been
touched or released), and that the host should read the new
key states over the serial interface. /CHANGE is pulled low
when a key state change has occurred.
Global: The AKS function operates across all ten keys. This
means that only one key can be active at any one time.
Groups: The AKS function operates among three groups of
keys: 0-1-4-5, 2-3-6-7, and 8-9. This means that up to
three keys can be active at any one time.
/CHANGE is very useful to prevent transmissions with
duplicate data. If /CHANGE is not used, the host would need
to keep polling the QT1101 constantly, even if there are no
changes in touch. Upon detection of a key, /CHANGE will
pull low and stay low until the serial interface has been
polled by the host. /CHANGE will then be released and
In Group mode, keys in one group have no AKS interaction
with keys in any other group.
return high until the next change of key state, either on or off , Note that in Fast Detect mode, AKS can only be off.
on any key (Figures 2.1, 2.4).
The /CHANGE pin is open-drain, and requires a ~100K
pullup resistor to Vdd in order to function properly.
2.7 MOD_0, MOD_1 Inputs
In full option mode, the MOD_0 and MOD_1 resistors are
used to set the 'Max On-Duration' recalibration timeouts. If a
key becomes stuck on for a lengthy duration of time, this
feature will cause an automatic recalibration event of that
specific key only once the specified on-time has been
exceeded. Settings of 10s, 60s, and infinite are available.
2.5 SYNC/LP Pin
The SYNC / LP pin function is configured according to the
SL_0 and SL_1 resistor connections to either Vdd or Vss,
according to the Table 1.5.
The Max On-Duration feature operates on a key-by-key
basis; when one key is stuck on, its recalibration has no
effect on other keys.
Sync mode: Sync mode allows the designer to synchronize
acquire bursts to an external signal source, such as mains
frequency (50/60Hz), to suppress interference. It can also be
used to synchronize two QT parts which operate near each
other, so that they will not cross-interfere if two or more of
the keys (or associated wiring) of the two parts are near
each other.
The logic combination on the MOD option pins sets the
timeout delay; see Table 1.3.
Simplified mode MOD timing: In simplified mode, the max
on-duration is fixed at 60 seconds.
The SYNC input is positive pulse triggered. If the SYNC input
does not change, the device will free-run at its own rate after
~150ms.
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QT1101 R4.06/0806
2.8 Fast Detect Mode
2.10 Unused Keys
In many applications, it is desirable to sense touch at high
speed. Examples include scrolling ‘slider’ strips or ‘Off’
buttons. It is possible to place the device into a ‘Fast Detect’
mode that usually requires under 15ms to respond. This is
accomplished internally by setting the Detect Integrator to
only two counts, i.e. only two successive detections are
required to detect touch.
Unused keys should be disabled by removing the
corresponding Cs, Rs, and Rsns components and
connecting SNS pins as shown in the ‘Unused’ column of
Table 1.1. Unused keys are ignored and do not factor into
the AKS function (Section 2.6).
2.11 Serial 1W Interface
In LP mode, ‘Fast’ detection will not speed up the initial
delay (which could be up to 360ms typical depending on the
option setting). However, once a key is detected the device
is forced back into normal speed mode. It will remain in this
faster mode until another LP pulse is received.
The 1W serial interface is an RS-232 based auto baud rate
serial asynchronous interface that requires only one wire
between the host MCU and the QT1101. The serial data are
extremely short and simple to interpret.
Auto baud rate detection takes place by having the host
device send a specific character to the QT1101, which
allows the QT1101 to set its baud rate to match that of the
host.
When used in a ‘slider’ application, it is normally desirable to
run the keys without AKS.
In both normal and ‘Fast’ modes, the time required to
process a key release is the same: it takes six sequential
confirmations of non-detection to turn a key off.
One feature of this method is that the baud rate can be any
rate between 8,000 and 38,400 bits per second. Neither the
QT1101 nor the host device has to be accurate in their
transmission rates, i.e. crystal control is not required.
Fast Detect mode can be enabled as shown in Tables 1.2
and 1.6.
Depending on the timing of a 1W host transmission, the
QT1101 device may need to abort an acquisition burst, and
rerun it after the transmission is complete and a reply has
been sent. As a consequence, each host request can
potentially result in a small, unnoticeable increase in
detection delay.
2.9 Simplified Mode
A simplified operating mode which does not require the
majority of option resistors is available. This mode is set by
connecting a resistor labeled SMR between pins SNS6K and
SNS7. (see Figure 1.2).
1W Connection: The 1W pin should be pulled high with a
resistor. When not in use it floats high, hence this causes no
increase in supply current.
In this mode there is only one option available - AKS enable
or disable. When AKS is disabled, Fast Detect mode is
enabled; when AKS is enabled, Fast Detect mode is off.
During transmission from the host, the host may drive the
1W line with either an open-drain or a push-pull driver.
However, if the host uses push-pull driving, it must release
the 1W line as soon as it is done with its stop bit so that
there is no drive conflict when the QT1101 sends its reply.
AKS in this mode is global only (i.e. operates across all
functioning keys).
The other option features are fixed as follows:
DETECT Pin: Push-pull, active high
SYNC/LP Function: LP mode, ~200ms response time
Max On-Duration: 60 seconds
If open-drain transmission is used by the host, the value of
the pull-up resistor should be optimized for the desired baud
rate: faster rates require a lower value of resistor to prevent
rise-time problems. A typical value for 19,200 baud might be
100K✡. An oscilloscope should be used to confirm that the
resistor is not causing excessive timing skew that might
cause bit errors.
See also Tables 1.6 and 1.7.
The QT1101 uses push-pull drive to transmit
data out on the 1W line back to the host. When
the stop bit level is established, 1W is floated;
for this reason, a pull-up resistor should always
be used on the 1W pin to prevent the signal from
drifting to an undefined state. A 100K✡ pull-up
resistor on 1W is recommended, unless the host
uses open-drain drive to the QT1101, in which
case a lower value may be required (see prior
paragraph).
Figure 2.1 Basic 1W Sequence
driven reply
from QT1101
(2 bytes)*
request
from host
(1 byte)
key state
change
1W
/CHANGE floating
floating
floating
floating
2.11.1 Basic 1W Operation
1 ~ 3 bit periods
*See Figure 2.3
The basic sequence of 1W serial operation is
shown in Figure 2.1. The 1W line is bi-directional
and must be pulled high with a resistor to
prevent a floating, undefined state (see previous
section).
Figure 2.2 1W UART Host Pattern
1W
(from host)
Serial bits
S 0 1 2 3 4 5 6 7 S
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7
QT1101 R4.06/0806
Oscillator Tolerance: While
the auto baud rate detection
mechanism has a wide
Figure 2.3 UART Response Pattern on 1W Pin
floating
tolerance for oscillator error,
the QT’s oscillator should still
floating
floating
1W
(from QT1101)
not vary by more than ±20%
from the recommended value.
Beyond a 20% error,
Serial bits
S 0 1 2 3 4 5 6 7 S
0 1 2 3 4 5
S 0 1 2 3 4 5 6 7 S
6 7 8 9 U U
communications at either the
lower or upper stated limits
could fail. The oscillator
frequency can be checked
with an oscilloscope by
Associated key #
* *
* *
(Shown with keys 0, 2 and 7 detecting)
* Fixed bit values
U - Unused bits
probing the pulse width on
QT1101 will be at full speed, and hence will always respond
to ‘P’ requests.
the SNS lines; these should ideally be 2.15µs in width each
at the beginning of a burst with the recommended
spread-spectrum circuit, or 2µs wide if no spread-spectrum
circuit is used.
Note that when sleeping in LP mode, there are by definition
no keys active, so there should not be a reason for the host
to send the ‘P’ query command in the first place.
Host Request Byte: The host requests the key state from
the QT1101 by sending an ASCII "P" character (ASCII
decimal code 80, hex 0x50) over the 1W line. The character
is formatted according to conventional RS-232:
Three strategies are available to the host to ensure that LP
mode operates correctly:
# /CHANGE used. The host monitors /CHANGE, and only
sends a ‘P’ request when it is low. The part is awake by
definition when /CHANGE is low. If /CHANGE is high,
key states are known to be unchanged since the last
reply received from the QT1101, and so additional ‘P’
requests are not needed. Before triggering LP mode the
host should wait for /CHANGE to go high after all keys
have become inactive.
8 data bits
no parity
1 stop bit
baud rate: 8,000 - 38,400
Figure 2.2 shows the bit pattern of the host request byte
(‘P’). The first bit labeled ‘S’ is the start bit, the last ‘S’ is the
stop bit. This bit pattern should never be changed. The
QT1101 will respond at the same baud rate as the received
‘P’ character.
# DETECT used. The host monitors DETECT, and if it is
active (i.e. the part is awake) it polls the device regularly
to obtain key status. When DETECT is inactive (the part
may be sleeping) no requests are sent because it is
known that no keys are active. Before triggering LP
mode the host should wait for DETECT to become
inactive, and then send one additional 'P' request to
ensure /CHANGE is also made inactive.
After sending the ‘P’ character the host must immediately
float the 1W signal to prevent a drive conflict between the
host and the QT1101 (see Figure 2.1). The delay from the
received stop bit to the QT1101 driving the 1W pin is in the
range 1-3 bit periods, so the host should float the pin within
one bit period to prevent a drive conflict.
# Neither /CHANGE nor DETECT used. The host polls
the device regularly to obtain key status, with a timeout
in operation when awaiting the reply to each ‘P’ request.
Not receiving a reply within the timeout period only
occurs when the part is sleeping, and hence when no
keys are active. Before triggering LP mode the host
should wait for all keys to become inactive and then
send an additional 'P' request to the QT1101 to ensure
/CHANGE is also inactive.
Data Reply: Before sending a reply, the QT1101 returns the
/CHANGE signal to its inactive (float-high) state.
The QT1101 then replies by sending two eight-bit characters
to the host over the 1W line using the same baud rate as the
request. With no keys pressed, both repl y bytes are ASCII
‘@’ (0x40) characters; any keys that are pressed at the time
of the reply result in their associated bits being set in the
reply. Figure 2.3 shows the reply bytes when keys 0, 2 and 7
are pressed - 0x45, 0x42, and the associations between
keys and bits in the reply.
2.11.3 2W Operation
1W operation, as described above, requires that the host
float the 1W line while awaiting a reply from the QT1101; this
is not always possible.
The QT1101 floats the 1W pin again after establishing the
level of the stop bit.
2.11.2 LP Mode Effects on 1W
The use of low power (LP) mode
presents some additional 1W timing
requirements. In LP mode (Section
2.5), the QT1101 will only respond to
a request from the host when it is
Figure 2.4 2W Operation
driven reply
from QT1101
(2 bytes)
request
from host
(1 byte)
key state
change
making one of its infrequent checks
for a key press. Hence, in that
RX
(from host)
condition most requests from the host
to the QT1101 will be ignored, since
the QT1101 will be sleeping and
unresponsive. However, if either
/CHANGE or DETECT are active the
1W
floating
floating
(from QT1101)
/CHANGE
floating
floating
1 ~ 3 bit periods
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8
QT1101 R4.06/0806
To solve this problem, the QT1101 can also receive the ‘P’
character from the host on its ‘Rx’ pin separately from the
The spread-spectrum circuit can be eliminated if it is not
desired (see Section 3.1). Non spread-spectrum mode
1W pin (Figure 2.4). The host need not float the Rx line since consumes significantly less current in one of the LP modes.
the QT1101 will never try to drive it.
The spread-spectrum RC network might need to be modified
Following a ‘P’ on Rx, the QT1101 will send the same
slightly with longer burst lengths. The sawtooth waveform
response pattern (Figure 2.3) over the 1W line as in pure 1W observed on SS should reach a crest height as follows:
mode.
Vdd >= 3.6V: 17% of Vdd
All other comments and timings given for 1W operation are
applicable for 2W operation. LP operation is the same for
2W mode as for 1W.
Vdd < 3.6V: 20% of Vdd
The Css capacitor connected to SS (Figures 1.1 and 1.2)
should be adjusted so that the waveform approximates the
above amplitude, ±10%, during normal operation in the
target circuit. If this is done, the circuit will give a spectral
modulation of 12-15%.
If the Rx pin is not used, it must be tied to Vdd.
3 Design Notes
3.1 Oscillator Frequency
The QT1101’s internal oscillator runs from an external
network connected to the OSC and SS pins as shown in
Figures 1.1 and 1.2. The charts in these figures show the
recommended values to use depending on nominal
operating voltage and spread spectrum mode.
3.3 Cs Sample Capacitors - Sensitivity
The Cs sample capacitors accumulate the charge from the
key electrodes and determine sensitivity. Higher values of Cs
make the corresponding sensing channel more sensitive.
The values of Cs can differ for each channel, permitting
differences in sensitivity from key to key or to balance
unequal sensitivities. Unequal sensitivities can occur due to
key size and placement differences and stray wiring
capacitances. More stray capacitance on a sense trace will
desensitize the corresponding key; increasing the Cs for that
key will compensate for the loss of sensitivity.
If spread spectrum mode is not used, only resistor Rb1
should be used, the Css capacitor eliminated, and the SS
pin pulled to Vss with a 100K resistor.
The Cs capacitors can be virtually any plastic film or low to
medium-K ceramic capacitor. The ‘normal’ Cs range is 2 .2nF
to 50nF depending on the sensitivity required; larger values
of Cs require better quality to ensure reliable sensing.
Acceptable capacitor types for most uses include PPS film,
polypropylene film, and NP0 and X7R ceramics. Lower
grades than X7R are not advised.
An out-of-spec oscillator can induce timing problems such as
large variations in Max On-Duration times and response
times as well as on the serial port.
Effect on serial communications: The oscillator frequency
has no nominal effect on serial communications since the
baud rate is set by an auto-sensing mechanism. However, if
the oscillator is too far outside the recommended settings,
the possible range of serial communications can shrink. For
example, if the oscillator is too slow, the upper baud rate
range can be reduced.
The required values of Cs can be noticeably affected by the
presence and connection of the option resistors.
3.4 Power Supply
The burst pulses should always be in the range of 1.8-2.4µs
at the start of a burst to allow the serial port to operate at its
specified limits; in spread-spectrum mode, the first pulses of
a burst should ideally be 2.15µs. In non spread-spectrum
mode, the target value is 2µs. If in doubt, make the pulses
on the narrower side (i.e. a faster oscillator) when using the
higher baud rates, and conversely on the wider side when
using the lowest baud rates.
The power supply can range from 2.8V to 5.0V. If this
fluctuates slowly with temperature, the device will track and
compensate for these changes automatically with only minor
changes in sensitivity. If the supply voltage drifts or shifts
quickly, the drift compensation mechanism will not be able to
keep up, causing sensitivity anomalies or false detections.
The power supply should be locally regulated using a
three-terminal device, to between 2.8V and 5.0V. If the
supply is shared with another electronic system, care should
be taken to ensure that the supply is free of digital spikes,
sags, and surges which can cause adverse effects.
3.2 Spread Spectrum Circuit
The QT1101 offers the ability to spectrally spread its
frequency of operation to heavily reduce susceptibility to
external noise sources and to limit RF emissions. The SS pin
is used to modulate an external passive RC network that
modulates the OSC pin. OSC is the main oscillator current
input. The circuits and recommended values are shown in
Figures 1.1 and 1.2.
For proper operation a 0.1µF or greater bypass capacitor
must be used between Vdd and Vss. The bypass capacitor
should be routed with very short tracks to the device’s Vss
and Vdd pins.
The resistors Rb1 and Rb2 should be changed depending
on Vdd. As shown in Figures 1.1 and 1.2, three sets of
values are recommended for these resistors depending on
Vdd. The power curves in Section 4.6 also show the effect of
these resistors.
3.5 PCB Layout and Construction
Refer to Quantum application note AN-KD02 for information
related to layout and construction matters.
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9
QT1101 R4.06/0806
4 Specifications
4.1 Absolute Maximum Specifications
Operating temperature, Ta. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -40 ~ +85ºC
Storage temp, Ts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -50 ~ +125ºC
Vdd. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 ~ +6.0V
Max continuous pin current, any control or drive pin. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±20mA
Short circuit duration to ground or Vdd, any pin. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . infinite
Voltage forced onto any pin. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3V ~ (Vdd + 0.3) Volts
4.2 Recommended Operating Conditions
Operating temperature, Ta. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -40 ~ +85ºC
V
DD. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +2.8 ~ +5.0V
Short-term supply ripple+noise. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±5mV/s
Long-term supply stability. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±100mV
Cs range. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.2 ~ 100nF
Cx range. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0 ~ 50pF
4.3 AC Specifications
Vdd = 5.0V, Ta = recommended, Cx = 5pF, Cs = 4.7nF; circuit of Figure 1.1
Parameter Description
Min
Typ
300
124
15
Max
Units
ms
Notes
Trc
Fc
Recalibration time
Burst center frequency
Burst modulation, percent
Sample pulse duration
Startup time from cold start
Burst duration
kHz
%
Fm
Tpc
Tsu
Tbd
Tdf
Tdn
Tdl
Total deviation
All 3 bursts
2
µs
450
6.5
15
ms
ms
Response time - Fast mode
Response time - normal mode
Response time - LP mode
Release time - all modes
Serial communications speed
ms
40
ms
200
40
ms
200ms LP setting
End of touch
Tdr
bps
ms
8,000
38,400
baud
4.4 DC Specifications
Vdd = 5.0V, Ta = recommended, Cx = 5pF, Cs = 4.7nF, Ta = recommended range; circuit of Figure 1.1 unless noted
Parameter Description
Min
Typ
Max
Units
Notes
Iddn
Average supply current,
normal mode*
4.5
2.7
2.1
1.9
1.5
8
mA
@ Vdd = 5.0
@ Vdd = 4.0
@ Vdd = 3.6
@ Vdd = 3.3
@ Vdd = 2.8
Iddl
Average supply current,
LP mode*
75
µA
@ Vdd = 3.0; 200ms LP mode
Vdds
Average supply turn-on slope
100
V/s
Req’d for startup, w/o external reset
ckt
Vil
Vhl
Vol
Voh
Iil
Low input logic level
High input logic level
Low output voltage
High output voltage
Input leakage current
Acquisition resolution
0.7
0.5
±1
V
V
3.5
V
7mA sink
Vdd-0.5
V
2.5mA source
µA
bits
Ar
8
*No spread spectrum circuit
Lq
10
QT1101 R4.06/0806
4.5 Signal Processing
Vdd = 5.0V, Ta = recommended, Cx = 5pF, Cs = 4.7nF, 2µs QT Pulses
Description
Value
Units
Notes
Detection threshold
10
counts
counts
counts
secs
Threshold for increase in Cx load
Detection hysteresis
2
Anti-detection threshold
6
Threshold for decrease of Cx load
Time to recalibrate if Cx load has exceeded anti-detection threshold
Must be consecutive or detection fails
Must be consecutive or detection fails
Option pin selected
Anti-detection recalibration delay
Detect Integrator filter, normal mode
Detect Integrator filter, Fast mode
Max On-Duration
2
6
2
samples
samples
secs
10, 60, inf
2,000
500
Normal drift compensation rate
Anti drift compensation rate
ms/level
ms/level
Towards increasing Cx load
Towards decreasing Cx load
Lq
11
QT1101 R4.06/0806
4.6 Idd Curves
Cx = 5pF, Cs = 4.7nF, Ta = 20oC, Spread spectrum circuit (see Fig. 1.1).
QT1101 Idd (normal mode) mA
QT1101 Idd (120ms response) µA
5.0
4.0
3.0
2.0
1.0
0.0
700
600
500
400
300
200
100
0
Rb1=12K
Rb2=22K
Rb1=15K
Rb2=27K
Rb1=12K
Rb2=22K
Rb1=15K
Rb2=27K
Rb1=12K
Rb2=27K
Rb1=12K
Rb2=27K
2.5
3
3.5
4
4.5
5
5.5
2.5
3
3.5
4
4.5
5
5.5
Vdd(V)
Vdd(V)
QT1101 Idd (200ms response) µA
QT1101 Idd (360ms response) µA
400
300
200
100
0
300
250
200
150
100
50
Rb1=12K
Rb2=22K
Rb1=15K
Rb2=27K
Rb1=12K
Rb2=22K
Rb1=15K
Rb2=27K
Rb1=12K
Rb2=27K
Rb1=12K
Rb2=27K
0
2.5
3
3.5
4
4.5
5
5.5
2.5
3
3.5
4
4.5
5
5.5
Vdd(V)
Vdd(V)
Cx = 5pF, Cs = 4.7nF, Ta = 20oC, No spread spectrum circuit (see Fig. 1.1).
QT1101 Idd (normal mode) mA
QT1101 Idd (120ms response) µA
5.0
4.0
3.0
2.0
1.0
0.0
600
500
400
300
200
100
0
Rb1=20K
Rb1=20K
Rb1=18K
Rb1=15K
Rb1=18K
Rb1=15K
2.5
3
3.5
4
4.5
5
5.5
2.5
3
3.5
4
4.5
5
5.5
Vdd(V)
Vdd(V)
QT1101 Idd (200ms response) µA
QT1101 Idd (360ms response) µA
300
250
200
150
100
50
150
125
100
75
Rb1=20K
Rb1=20K
50
Rb1=18K
Rb1=15K
Rb1=18K
Rb1=15K
25
0
0
2.5
3
3.5
4
4.5
5
5.5
2.5
3
3.5
4
4.5
5
5.5
Vdd(V)
Vdd(V)
lQ
12
QT1101 R4.06/0806
4.7 LP Mode Typical Response Times
Response Time vs Vdd - 120ms Setting
Response Time vs Vdd - 200ms Setting
130
240
230
220
210
200
190
180
170
160
125
120
115
110
105
100
95
90
2.5
3
3.5
4
4.5
5
5.5
2.5
3
3.5
4
4.5
5
5.5
Vdd
Vdd
Response Time vs Vdd - 360ms Setting
430
410
390
370
350
330
310
290
2.5
3
3.5
4
4.5
5
5.5
Vdd
lQ
13
QT1101 R4.06/0806
4.8 Mechanical - 32-QFN Package
Dimensions In Millimeters
Symbol Minimum Nominal Maximum
A
A1
b
C
D
D2
E
E2
e
L
y
0.70
0.00
0.18
-
4.90
3.05
4.90
3.05
-
-
0.02
0.25
0.20 REF
5.00
-
5.00
-
0.50
0.40
-
0.90
0.05
0.32
-
5.10
3.65
5.10
3.65
-
0.30
0.00
0.50
0.075
Note that there is no functional requirement for the large pad on the underside of the 32-QFN
package to be soldered to the substrate. If the final application does require this area to be soldered
for mechanical reasons, the pad(s) to which it is soldered to must be isolated and contained under
the 32-QFN footprint only.
Lq
14
QT1101 R4.06/0806
4.9 Mechanical - 48-SSOP Package
A
B
C
G
J
H
D
a
F
E
All dimensions in millimeters
A
10.03
10.67
B
7.39
7.59
C
0.20
0.30
D
2.16
2.51
E
F
0.10
0.25
G
15.57
16.18
H
0.10
0.30
J
0.64
0.89
a
Min
Max
0o
8o
0.64
Typ
4.10 Part Marking
32-QFN
48-SSOP
QRG Part
No.
QT1101-IS48G; 48 SSOP
QRG
Revision
Code
QT1101
QT1101-IS48G
© QRG 1976 R4
QProxTM
©QRG 4
YYWWG
run nr.
<datecode#>
DIMPLE
'YY' = Year of manufacture:
'WW' = Week of manufacture:
'G' = Green/RoHS Compliant.
Pin 1
Pin 1
Identification
'run nr.' = 6 Digit Run Number
Lq
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QT1101 R4.06/0806
LQ
Copyright © 2005-2006 QRG Ltd. All rights reserved.
Patented and patents pending
Corporate Headquarters
1 Mitchell Point
Ensign Way, Hamble SO31 4RF
Great Britain
Tel: +44 (0)23 8056 5600 Fax: +44 (0)23 8045 3939
www.qprox.com
North America
651 Holiday Drive Bldg. 5 / 300
Pittsburgh, PA 15220 USA
Tel: 412-391-7367 Fax: 412-291-1015
This device is covered under one or more United States and corresponding international patents. QRG patent numbers can be found
online at www.qprox.com. Numerous further patents are pending, which may apply to this device or the applications thereof.
The specifications set out in this document are subject to change without notice. All products sold and services supplied by QRG are
subject to our Terms and Conditions of sale and supply of services which are available online at www.qprox.com and are supplied with
every order acknowledgement. QRG trademarks can be found online at www.qprox.com. QRG products are not suitable for medical
(including lifesaving equipment), safety or mission critical applications or other similar purposes. Except as expressly set out in QRG's
Terms and Conditions, no licenses to patents or other intellectual property of QRG (express or implied) are granted by QRG in
connection with the sale of QRG products or provision of QRG services. QRG will not be liable for customer product design and
customers are entirely responsible for their products and applications which incorporate QRG's products.
Development Team: John Dubery, Alan Bowens, Matthew Trend
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