IQS6204DNR [ETC]
Unique combination of sensing:Capacitive sensing;型号: | IQS6204DNR |
厂家: | ETC |
描述: | Unique combination of sensing:Capacitive sensing |
文件: | 总63页 (文件大小:2429K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
IQ Switch
ProxFusion Series
IQS620 Datasheet
Combination sensor with dual channel capacitive proximity/touch, Hall-effect sensor and
inductive sensing
The IQS620 ProxFusion IC is a multifunctional capacitive, Hall-effect & inductive sensor designed
for applications where any or all of the technologies may be required. The IQS620 is an ultra-low
power solution designed for short or long term activations through any of the sensing channels. The
IQS620 is fully I2C compatible and can be configured to output main trigger events on GPIOs.
Features
Unique combination of sensing
technologies:
Multiple integrated UI
options based on years
o Capacitive sensing
of
experience
in
sensing on fixed and
mobile platforms:
o Proximity / Touch
o Proximity wake-up
o Hall-effect sensing
o Inductive sensing
Capacitive sensing
o 2pF to 200pF external capacitive load
capability
DFN10
Representations only, not
actual markings
o SAR with movement
o Fully adjustable sensing options
and quick release
Hall-effect sensing
Automatic Tuning Implementation (ATI) –
performance enhancement (10bit)
o No external components required
o Dual direction Hall switch sensor
o 2 level detection (widely variable)
o Detection range 1mT – 100mT
Inductive sensing
o Metal sensing UI with 2 level detection
and hysteresis
o Only external sense coil required (PCB
Minimal external components
Standard I2C interface (polling with sub 1ms
clock stretching)
Optional RDY indication for event mode
operation
Event or Streaming mode
Supply voltage: 1.8V to 3.3V
Low profile DFN(3x3) – 10 pin package
trace)
Low power consumption: 300uA (50 Hz
response, all technologies in use), 2.5uA
(low power mode, zoom to scanning mode
with wake-up)
Applications
Mobile electronics (phones/tablets)
Human Interface Devices
SAR safety requirements for laptops,
Proximity activated backlighting
Applications with long-term activation
Aftermarket automotive1
tablets and phones
Wearable devices
White goods and appliances
Available Packages
TA
DFN(3x3) - 10
-40°C to 85°C
IQS620
1 The part is not automotive qualified.
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 1 of 63
November 2016
IQ Switch
ProxFusion Series
Table of Contents
LIST OF ABBREVIATIONS............................................................................................................................................. 4
1
INTRODUCTION.................................................................................................................................................. 5
1.1
PROXFUSION...................................................................................................................................................... 5
PACKAGING AND PIN-OUT ....................................................................................................................................... 5
REFERENCE SCHEMATIC ........................................................................................................................................... 6
SENSOR CHANNEL COMBINATIONS ............................................................................................................................. 6
1.2
1.3
1.4
2
CAPACITIVE SENSING ......................................................................................................................................... 7
®
2.1
INTRODUCTION TO PROXSENSE ................................................................................................................................ 7
CHANNEL SPECIFICATIONS ........................................................................................................................................ 7
HARDWARE CONFIGURATION.................................................................................................................................... 8
SOFTWARE CONFIGURATION..................................................................................................................................... 9
SENSOR DATA OUTPUT AND FLAGS............................................................................................................................. 9
2.2
2.3
2.4
2.5
3
4
5
HALL-EFFECT SENSING.......................................................................................................................................10
3.1
INTRODUCTION TO HALL-EFFECT SENSING ................................................................................................................. 10
CHANNEL SPECIFICATIONS ...................................................................................................................................... 10
HARDWARE CONFIGURATION.................................................................................................................................. 11
SOFTWARE CONFIGURATION................................................................................................................................... 12
SENSOR DATA OUTPUT AND FLAGS........................................................................................................................... 13
3.2
3.3
3.4
3.5
INDUCTIVE SENSING..........................................................................................................................................14
4.1
INTRODUCTION TO INDUCTIVE SENSING..................................................................................................................... 14
CHANNEL SPECIFICATIONS ...................................................................................................................................... 14
HARDWARE CONFIGURATION.................................................................................................................................. 15
SOFTWARE CONFIGURATION................................................................................................................................... 15
SENSOR DATA OUTPUT AND FLAGS........................................................................................................................... 16
4.2
4.3
4.4
4.5
TEMPERATURE SENSING ...................................................................................................................................17
5.1
INTRODUCTION TO TEMPERATURE SENSING ............................................................................................................... 17
CHANNEL SPECIFICATIONS ...................................................................................................................................... 17
HARDWARE CONFIGURATION.................................................................................................................................. 18
SOFTWARE CONFIGURATION................................................................................................................................... 18
SENSOR DATA OUTPUT AND FLAGS........................................................................................................................... 19
5.2
5.3
5.4
5.5
6
7
8
DEVICE CLOCK, POWER MANAGEMENT AND MODE OPERATION......................................................................20
6.1
DEVICE MAIN OSCILLATOR...................................................................................................................................... 20
DEVICE MODES .................................................................................................................................................... 20
REPORT RATES ..................................................................................................................................................... 21
SYSTEM RESET ..................................................................................................................................................... 21
6.2
6.3
6.4
COMMUNICATION ............................................................................................................................................22
7.1
I2C MODULE SPECIFICATION.................................................................................................................................... 22
DEVICE ADDRESS AND SUB-ADDRESSES ..................................................................................................................... 22
ADDITIONAL OTP OPTIONS .................................................................................................................................... 22
RECOMMENDED COMMUNICATION AND RUNTIME FLOW DIAGRAM................................................................................ 23
7.2
7.3
7.4
MEMORY MAP ..................................................................................................................................................24
8.2
DEVICE INFORMATION DATA .................................................................................................................................. 26
FLAGS AND USER INTERFACE DATA ........................................................................................................................... 27
CHANNEL COUNTS (RAW DATA)............................................................................................................................... 32
LTA VALUES (FILTERED DATA)................................................................................................................................. 32
PROXFUSION SENSOR SETTINGS BLOCK 0................................................................................................................... 33
PROXFUSION SENSOR SETTINGS BLOCK 1................................................................................................................... 37
8.3
8.4
8.5
8.6
8.7
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 2 of 63
November 2016
IQ Switch
ProxFusion Series
8.8
8.9
PROXFUSION UI SETTINGS ..................................................................................................................................... 40
SAR UI SETTINGS................................................................................................................................................. 41
METAL DETECTION UI SETTINGS .............................................................................................................................. 43
HALL-EFFECT SENSOR SETTINGS............................................................................................................................... 45
HALL-EFFECT SWITCH UI SETTINGS........................................................................................................................... 47
TEMPERATURE UI SETTINGS ................................................................................................................................... 48
DEVICE AND POWER MODE SETTINGS ....................................................................................................................... 50
8.10
8.11
8.12
8.13
8.14
9
ELECTRICAL CHARACTERISTICS ..........................................................................................................................54
9.1
ABSOLUTE MAXIMUM SPECIFICATIONS..................................................................................................................... 54
POWER ON-RESET/BROWN OUT ............................................................................................................................. 54
DIGITAL INPUT/OUTPUT TRIGGER LEVELS................................................................................................................... 54
CURRENT CONSUMPTIONS ..................................................................................................................................... 55
CAPACITIVE LOADING LIMITS................................................................................................................................... 57
HALL-EFFECT MEASUREMENT LIMITS ........................................................................................................................ 57
INDUCTIVE MEASUREMENT LIMITS ........................................................................................................................... 57
9.2
9.3
9.4
9.5
9.6
9.7
10 PACKAGE INFORMATION ..................................................................................................................................58
10.1
10.2
10.3
10.4
10.5
DFN10 PACKAGE AND FOOTPRINT SPECIFICATIONS..................................................................................................... 58
DEVICE MARKING (SUBJECTED TO CHANGE FOR PRODUCTION)....................................................................................... 59
ORDERING INFORMATION ...................................................................................................................................... 59
TAPE AND REEL SPECIFICATION ................................................................................................................................ 60
MSL LEVEL ......................................................................................................................................................... 61
11 DATASHEET REVISIONS .....................................................................................................................................62
11.1
11.2
REVISION HISTORY ................................................................................................................................................ 62
ERRATA.............................................................................................................................................................. 62
APPENDIX A. CONTACT INFORMATION .....................................................................................................................63
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 3 of 63
November 2016
IQ Switch
ProxFusion Series
List of abbreviations
ATI – Automatic Tuning Implementation
LTA – Long term average
SAR – Specific absorption rate
UI – User interface
AC – Alternating current
DSP – Digital signal processing
RX – Receiving electrode
LTX – Inductive transmitting electrode
CS – Sampling capacitor
NP – Normal power
LP – Low power
ULP – Ultra low power
ACK – I2C Acknowledge condition
NACK – I2C Not Acknowledge condition
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 4 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
1 Introduction
1.1 ProxFusion
The ProxFusion sensor series provides all of the proven ProxSense® engine capabilities with
additional sensors types. A combined sensor solution is available within a single platform.
1.2 Packaging and Pin-Out
SDA
RDY/GPIO0
VDDHI
VSS
VDDHI
SCL
RX1
VREG
RX0
LTX/GPIO3
Figure 1.1
Name
IQS620 pin-out (DFN10 package; device markings may differ)
Table 1.1 Pin-out description
IQS620 in DFN10
Pin
Type
Digital input / output
Function
SDA (I2C Data signal)
1
SDA
Configurable digital output SAR activation output (higher priority)
GPIO0 /
RDY
2
3
4
Open drain active low logic RDY (I2C Ready interrupt signal; lower priority)
VDDHI
Supply input
Supply: 1.8V – 3.3V
Regulates the system’s internal voltage
Requires external capacitors to ground
VREG
Regulator output
Configurable digital output
PWM output /
Transmitter electrode
PWM signal output (higher priority) /
Connect to inductive sensor’s transmitting coil
(lower priority)
GPIO3 /
LTX
5
Connect to conductive area intended for sensor
receiving
6
7
RX0
RX1
Receiving electrode
Receiving electrode
Connect to conductive area intended for sensor
receiving
SCL (I2C Clock signal)
8
SCL
Digital input / output
Supply input
9
VDDHI
VSS
Supply: 1.8V – 3.3V
10
Signal GND
Common ground reference
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 5 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
1.3 Reference schematic
Figure 1.2
IQS620 reference schematic
1.4 Sensor channel combinations
The table below summarizes the IQS620’s sensor and channel associations.
Table 1.2
CH0
Sensor - channel allocation
Sensor / UI
type
CH1
CH2
CH3
CH4
CH5
Self capacitive
SAR UI self
o
o
o
o
Main
Movement
Hall-effect
switch UI
Positive
Negative
Mutual
inductive
o
o
Temperature
trip and
sensing
Key:
o - Optional implementation
- Fixed use for UI
Copyright © Azoteq 2016
IQS620 Preliminary pre-production datasheet revision 0.91
Page 6 of 63
November 2016
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
All Rights Reserved
IQ Switch
ProxFusion Series
2 Capacitive sensing
2.1 Introduction to ProxSense®
Building on the previous successes from the ProxSense® range of capacitive sensors, the same
fundamental sensor engine have been implemented in the ProxFusion series.
The capacitive sensing capabilities of the IQS620 include:
Self-capacitive sensing.
Maximum of 3 capacitive channels to be individually configured.
o Prox and touch adjustable thresholds
o Individual sensitivity setups
o Alternative ATI modes
Enhanced SAR user interface:
o For passing the SAR qualification
o Movement sensing to distinguish between stationary in-contact objects and human
interference
o Quick release detection feature (fully configurable)
o GPIO output of SAR activation (on pin2: GPIO0) for MCU interrupt capability
Discreet button UI:
o Fully configurable 2 level threshold setup – Traditional Prox & Touch activation
levels.
o Customizable filter halt time
2.2 Channel specifications
The IQS620 provides a maximum of 3 channels available to be configured for capacitive sensing.
Each channel can be setup separately according to the channel’s associated settings registers.
There are two distinct capacitive user interfaces available to be used.
a) Self capacitive proximity/touch UI (always enabled)
b) SAR UI
When the SAR UI is activated (ProxFusion Settings4: bit7):
Channel 0 is used for as the main capacitive sensing channel for SAR detection.
Channel 1 is used for capacitive movement detection. This is used to improve the SAR
detection such as quick release detection.
Table 2.1
CH0
Capacitive sensing - channel allocation
Mode
Self
CH1
CH2
CH3
CH4
CH5
o
o
o
capacitive
SAR UI self
o
Main
Movement
Key:
o - Optional implementation
- Fixed use for UI
Copyright © Azoteq 2016
IQS620 Preliminary pre-production datasheet revision 0.91
Page 7 of 63
November 2016
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
All Rights Reserved
IQ Switch
ProxFusion Series
2.3 Hardware configuration
In the table below are multiple options of configuring sensing (Rx) electrodes to realize different
implementations (combinations not shown).
Table 2.2
Capacitive sensing - hardware description
Self capacitive configuration
RX1
1 button
RX0
RX1
RX0
2
buttons
RX1
SAR
antenna
RX0
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 8 of 63
November 2016
IQ Switch
ProxFusion Series
2.4 Software configuration
To be completed.
2.5 Sensor data output and flags
The following registers should be monitored by the master to detect capacitive sensor output and
SAR activations.
a) The Global events register (0x11) will show the IQS620’s main events. Bit0 is dedicated to
the ProxSense activations and two other bits (bit7 & bit1) is provided to show the state of the
SAR UI. SAR_ACTIVE (bit7) will be constantly active during SAR detection. SAR event (bit1)
will toggle upon each SAR qualified event or change of SAR status.
Global Events (0x11)
Bit
Number
Data
Access
7
R
6
R
5
4
R
3
R
2
R
1
R
0
R
R
PROX
SENSE
EVENT
SAR
ACTIVE EVENT
PMU
SYS
EVENT
TEMP
METAL
HALL
SAR
Name
EVENT DETECT EVENT EVENT
b) The ProxFusion UI flags (0x12) and SAR UI flags (0x13) provide more detail regarding the
outputs. A prox and touch output bit for each channel 0 to 3 is provided in the ProxFusion UI
flags register.
c) The SAR UI Flags (0x13) register will show detail regarding the state of the SAR output as
well as Quick release toggles, movement activations and the state of the filter (halted or not).
ProxFusion UI flags (0x12)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
Name
-
-
R
R
R
-
-
R
R
R
CH2_T
CH1_T
CH0_T
CH2_P
CH1_P CH0_P
SAR UI flags (0x13)
Bit
Number
Data
7
-
6
-
5
-
4
3
2
1
0
R
R
-
R
R
Access
SAR
ACTIVE
QUICK
RELEASE
MOVE-
MENT
Name
-
-
-
FHALT
The SAR UI can also be used with the inductive sensing capabilities and is explained in section
4.Inductive sensing as well.
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 9 of 63
November 2016
IQ Switch
ProxFusion Series
3 Hall-effect sensing
3.1 Introduction to Hall-effect sensing
The IQS620 has two internal Hall-effect sensing plates (on chip). No external sensing hardware is
required for Hall-effect sensing.
The Hall-effect measurement is essentially a current measurement of the induced current through
the Hall-effect-sensor plates produced by the magnetic field passing perpendicular through each
plate.
Advanced digital signal processing are performed to provide sensible output data.
Two threshold levels are provided (prox & touch).
Hall-effect output is linearized by inverting signals.
North/South field direction indication provided.
Differential Hall-Effect sensing:
o Removes common mode disturbances
o North-South field indication
3.2 Channel specifications
Channels 4 and 5 are dedicated to Hall-effect sensing. Channel 4 performs the positive direction
measurements and channel 5 will handle all measurements in the negative direction. These two
channels are used in conjunction to acquire differential Hall-effect data and will always be used as
input data to the Hall-effect UI’s.
There are two distinct Hall-effect user interfaces available:
a) General Hall-effect sensing
b) Hall-effect switch UI
Table 3.1
CH0
Hall-effect sensor – channel allocation
Mode
CH1
CH2
CH3
CH4
CH5
Hall-effect
switch UI
Smart cover
Slide switch
Positive
Negative
Key:
o - Optional implementation
- Fixed use for UI
Copyright © Azoteq 2016
IQS620 Preliminary pre-production datasheet revision 0.91
Page 10 of 63
November 2016
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
All Rights Reserved
IQ Switch
ProxFusion Series
3.3 Hardware configuration
Rudimentary hardware configurations
Axially polarized magnet (linear movement or magnet presence detection)
Hall-effect
push
switch
Smart
cover
Bar magnet (linear movement and magnet field detection)
Slide
switch
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 11 of 63
November 2016
IQ Switch
ProxFusion Series
3.4 Software configuration
To be completed.
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 12 of 63
November 2016
IQ Switch
ProxFusion Series
3.5 Sensor data output and flags
The following registers can be monitored by the master to detect Hall-effect related events.
a) Two bits in the Global events (0x11) register are dedicated to Hall-effect related output.
HALL_COVER_CLOSED (bit7) will provide the status of a Hall-effect cover implementation
(cover closed = 1 or cover open = 0). Bit2 will be toggled during any Hall-effect proximity
detection.
Global events (0x11)
Bit
Number
Data
7
R
6
R
5
R
4
R
3
2
1
0
R
R
R
R
Access
METAL
DETECT
EVENT
PROX
SENSE
EVENT
SAR
PMU
SYS
TEMP
HALL
EVENT
SAR
EVENT
Name
ACTIVE EVENT EVENT EVENT
b) The Hall-effect UI flags (0x16) register provides the standard two level activation output
(prox = HALL_POUT & touch = HALL_TOUT) as well as a HALL_N/S bit to indicate the
magnet polarity orientation.
Hall-effect UI flags (0x16)
Bit
7
6
5
4
3
2
1
0
Number
Data
-
-
-
-
-
R
R
R
Access
HALL
TOUT
HALL
POUT
HALL
N/S
Name
-
-
-
-
-
c) The Hall-effect UI output (0x17 & 0x18) registers provide a 16 bit value of the Hall-effect
amplitude detected by the sensor.
Hall-effect UI Output (0x17 - 0x18)
Bit
7
6
5
4
3
2
1
0
Number
Data
Access
Name
Bit
R
R
R
R
R
R
R
R
Hall-effect UI output low byte
15
R
14
R
13
R
12
R
11
R
10
R
9
8
Number
Data
Access
R
R
Name
Hall-effect UI output high byte
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 13 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
4 Inductive sensing
4.1 Introduction to inductive sensing
The IQS620 provides inductive sensing capabilities in order to detect the presence of metal/metal-
type objects. Prox and touch thresholds are widely adjustable and individual hysteresis settings are
definable for each.
4.2 Channel specifications
The IQS620 requires 3 sensing pins for mutual inductive sensing. The metal detect UI will be
executed using channel 2.
The mutual inductive user interface is available on channel 2.
a) Metal detect UI (Dedicated to CH2)
Table 4.1
CH0
Inductive sensor – channel allocation
Mode
CH1
CH2
CH3
CH4
CH5
Mutual
inductive
o
o
Key:
o - Optional implementation
- Fixed use for UI
Copyright © Azoteq 2016
IQS620 Preliminary pre-production datasheet revision 0.91
Page 14 of 63
November 2016
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
All Rights Reserved
IQ Switch
ProxFusion Series
4.3 Hardware configuration
Rudimentary hardware configurations (to be completed).
Table 4.2
Inductive hardware description
Mutual inductive
VSS
RX1
RX0
TX0
4.4 Software configuration
To be completed.
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 15 of 63
November 2016
IQ Switch
ProxFusion Series
4.5 Sensor data output and flags
The following registers can be monitored by the master to detect inductive sensor related events.
a) Global events (0x11) to prompt for inductive sensor activation. Bit3 denoted as
METAL_DETECT_EVENT will indicate the detection of a metal object using the inductive
sensing.
Global events (0x11)
Bit
Number
Data
Access
7
R
6
R
5
R
4
3
2
1
0
R
R
R
R
R
METAL
DETECT
EVENT
PROX
SENSE
EVENT
SAR
PMU
SYS
TEMP
EVENT
HALL
EVENT
SAR
EVENT
Name
ACTIVE EVENT EVENT
b) The Metal detect UI flags (0x13) register provides the classic prox/touch two level activation
outputs as well as a bit to distinguish whether the current counts are above or below the LTA.
Metal detect UI flags (0x13)
Bit
Number
7
6
5
4
3
2
-
1
-
0
-
Data
Access
R
R
R
-
-
Signed
output
Name
TOUCH
PROX
-
-
-
-
-
c) Metal detect UI output (0x14 & 0x15) registers will provide a combined 16-bit value to
acquire the magnitude of the inductive sensed object.
Metal detect UI output (0x14 - 0x15)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R
R
R
R
R
R
R
R
Name
Metal detect UI output low byte
Bit
Number
Data
Access
15
R
14
R
13
R
12
R
11
R
10
R
9
8
R
R
Name
Metal detect UI output high byte
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 16 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
5 Temperature sensing
5.1 Introduction to temperature sensing
The IQS620 provides temperature sensing capabilities which can be used for temperature change
monitoring or as an absolute temperature sensor (requires individual calibration). The use of the
temperature sensor is primarily to reseed other sensor channels to account for sudden changes in
environmental conditions.
The IQS620 uses a linearly proportional to absolute temperature sensor for temperature
measurement. The temperature output is given by,
푎
푇 =
+ 푐
푏. 퐶퐻3
Where 푎, 푏 푎푛푑 푐 are constants that are calculated during calibration. Additionally, the channel setup
must be calculated during testing.
5.2 Channel specifications
The IQS620 requires only external passive components to do temperature sensing (no additional
circuitry/components required). The temperature UI will be executed using data from channel 3 if
correctly setup for temperature sensing.
Table 5.1
CH0
Temperature sensor – channel allocation
Mode
CH1
CH2
CH3
CH4
CH5
Temperature
trip and
sensing
Key:
o - Optional implementation
- Fixed use for UI
Copyright © Azoteq 2016
IQS620 Preliminary pre-production datasheet revision 0.91
Page 17 of 63
November 2016
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
All Rights Reserved
IQ Switch
ProxFusion Series
5.3 Hardware configuration
No additional hardware required. Temperature sensing realized on-chip
5.4 Software configuration
To be completed.
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 18 of 63
November 2016
IQ Switch
ProxFusion Series
5.5 Sensor data output and flags
The following registers can be monitored by the master to detect temperature sensor related events.
d) Global events (0x11) to prompt for temperature trip activation. Bit4 denoted as
TEMP_EVENT will indicate the detection of a temperature event.
Global events (0x11)
Bit
Number
Data
Access
7
6
R
5
R
4
R
3
2
1
0
R
R
R
R
R
METAL
DETECT
EVENT
PROX
SENSE
EVENT
SAR
ACTIVE
PMU
SYS
TEMP
HALL
EVENT
SAR
EVENT
Name
EVENT EVENT EVENT
e) The Temperature UI flags (0x19) register provides a temperature trip activation output bit if
the condition of a temperature reseed threshold is tripped.
Temperature UI flags (0x19)
Bit
7
6
5
4
3
2
-
1
-
0
-
Number
Data
R
-
-
-
-
Access
Temp
trip
Name
-
-
-
-
-
-
-
f) Temperature UI output (0x1A & 0x1B) registers will provide a combined 16-bit value to
provide the absolute temperature measured in units of Kelvin (K).
Temperature UI output (0x1A – 0x1B)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R
R
R
R
R
R
R
R
Name
Temperature output low byte
Bit
Number
Data
Access
15
R
14
R
13
R
12
R
11
R
10
R
9
8
R
R
Name
Temperature output high byte
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Page 19 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
6 Device clock, power management and mode operation
6.1 Device main oscillator
The IQS620 has a 16MHz main oscillator (default enabled) to clock all system functionality.
An option exists to reduce the main oscillator to 4MHz. This will result in all system timings, charge
transfers and sample rates to be slower by half of the default implementations.
To set this option this:
o As a software setting – Set the System_Settings: bit4 = 1, via an I2C command.
o As a permanent setting – Set the OTP option in FG Bank 0: bit2 = 1, using Azoteq USBProg
program.
6.2 Device modes
The IQS620 supports the following modes of operation;
Normal mode (Fixed report rate)
Low power mode (Reduced report rate)
Ultra-low power mode (Only channel 0 is sensed for a prox)
Halt mode (Suspended/disabled)
Note: Auto modes must be disabled to enter or exit halt mode.
The device will automatically switch between the different operating modes by default. However this
Auto mode feature may be disabled by setting the DSBL_AUTO_MODE bit (Power_mode_settings
0xD2: bit5) to confine device operation to a specific power mode. The POWER_MODE bits
(Power_mode_settings 0xD2: bit4-3) can then be used to specify the desired mode of operation.
6.2.1 Normal mode
Normal mode is the fully active sensing mode to function at a fixed report rate specified in the Normal
Mode report Rate (0xD3) register. This 8-bit value is adjustable from 0ms – 255ms in intervals of
1ms.
Note: The device’s low power oscillator have an accuracy as specified in section 9.
6.2.2 Low power mode
Low power mode is a reduced sensing mode where all channels are sensed but at a reduced sample
rate. The sample rate can be specified in the Low Power Mode report Rate (0xD4) register. The 8-
bit value is adjustable from 0ms – 255ms in intervals of 1ms. Reduced report rates also reduce the
current consumed by the sensor.
Note: The device’s low power oscillator have an accuracy as specified in section 9.
6.2.3 Ultra-low power mode
Ultra-low power mode is a reduced sensing mode where only channel 0 is sensed and no other
channels or UI code are executed. Set the EN_ULP_MDE bit (Power_mode_settings: bit6) to enable
use of the ultra-low power mode. The sample rate can be specified in the Low Power Mode report
Rate (0xD5) register. The 8-bit value is adjustable from 0ms – 4sec in intervals of 16ms.
Wake up will occur on prox detection on channel 0.
6.2.4 Halt mode
Halt mode will suspend all sensing and will place the device in a dormant or sleep state. The device
requires an I2C command from a master to explicitly change the power mode out of the halt state
before any sensor functionality can continue.
Copyright © Azoteq 2016
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Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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November 2016
IQ Switch
ProxFusion Series
6.2.5 Mode time
The mode time is specified in the Auto Mode Timer (0xD6) register. The 8-bit value is adjustable
from 0ms – 2 min in intervals of 500ms.
6.3 Report rates
6.3.1 Calculation of each mode’s report rate
Normal power segment rate
To be completed.
Auto modes change rates
To be completed.
Streaming/event mode rates
To be completed.
6.4 System reset
The IQS620 device monitor’s system resets and events.
a) Every device power-on and reset event will set the Show Reset bit (System flags 0x10: bit7)
and the master should explicitly clear this bit by setting the ACK_RESET (bit6) in System
Settings.
b) The system events will also be indicated with the Global events register’s SYS_EVENT bit
(Global events 0x11: bit5) if any system event occur such as a reset. This event will
continuously trigger until the reset has been acknowledged.
Copyright © Azoteq 2016
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IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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November 2016
IQ Switch
ProxFusion Series
7 Communication
7.1 I2C module specification
The device supports a standard two wire I2C interface with the addition of an RDY (ready interrupt)
line. The communications interface of the IQS620 supports the following:
Streaming data as well as event mode.
The master may address the device at any time. If the IQS620 is not in a communication
window, the device will return an ACK after which clock stretching may be induced until a
communication window is entered. Additional communication checks are included in the
main loop in order to reduce the average clock stretching time.
The provided interrupt line (RDY) is an open-drain active low implementation and indicates
a communication window.
7.2 Device address and sub-addresses
The default device address is 0x44 = DEFAULT_ADDR.
Alternative sub-address options are definable in the following one-time programmable bits:
OTP Bank0 (bit3; 0; bit1; bit0) = SUB_ADDR_0 to SUB_ADDR_7
a) Default address:
b) Sub-address:
c) Sub-address:
d) Sub-address:
e) Sub-address:
f) Sub-address:
g) Sub-address:
h) Sub-address:
0x44 = DEFAULT_ADDR OR SUB_ADDR_0
0x45 = DEFAULT_ADDR OR SUB_ADDR_1
0x46 = DEFAULT_ADDR OR SUB_ADDR_2
0x47 = DEFAULT_ADDR OR SUB_ADDR_3
0x4C = DEFAULT_ADDR OR SUB_ADDR_4
0x4D = DEFAULT_ADDR OR SUB_ADDR_5
0x4E = DEFAULT_ADDR OR SUB_ADDR_6
0x4F = DEFAULT_ADDR OR SUB_ADDR_7
7.3 Additional OTP options
All one-time-programmable device options are located in OTP bank0.
OTP bank0
Bit
Number
7
6
5
-
4
3
2
1
0
SUB
ADDRESS
(bit3)
Internal COMMS
use ATI
SUB ADDRESS
(bit1-0)
Name
-
4MHz
Bit definitions:
Bit 7: Internal use
o Do not set. Leave bit cleared.
Bit 6: : Communication mode during ATI
o 0: No streaming events are generated during ATI
o 1: Communication continue as setup regardless of ATI state.
Bit 2: Main Clock frequency selection
o 0: Run FOSC at 16MHz
o 1: Run FOSC at 4MHz
Bit 3,1,0: I2C sub-address
o I2C address = 0x44 OR SUB_ADDR
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Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
7.4 Recommended communication and runtime flow diagram
The following is a basic master program flow diagram to communicate and handle the device. It
addresses possible device events such as output events, ATI and system events (resets).
POR
Reset
occured
Clear
Show_Reset
Show Reset?
Setup &
Initialization
No
Yes
ATI
IN ATI?
Yes
Runtime
No
No
Global Event?
System Event?
Yes
Valid event?
Yes
Retrieve
event data
Figure 7.1
Master command structure and runtime event handling flow diagram
It is recommended that the master verifies the status of the System_Flags0 bits to identify events
and resets. Detecting either one of these should prompt the master to the next steps of handling the
IQS620.
Streaming mode communication is used for detail sensor evaluation during prototyping and/or
development phases.
Event mode communication is recommended for runtime use of the IQS620. This reduce the
communication on the I2C bus and report only triggered events.
Copyright © Azoteq 2016
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IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 23 of 63
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IQ Switch
ProxFusion Series
8 Memory map
The full memory map is summarized below. Register groups are explained in the latter subsections.
Table 8.1
IQS620 Memory map index
Full
Address
Group Name
Item Name
Data Access
0x00
0x01
0x02
0x10
0x11
0x12
0x13
0x14
0x15
0x16
0x17
0x18
0x19
0x1A
0x1B
0x20
0x21
0x22
0x23
0x24
0x25
0x26
0x27
0x28
0x29
0x2A
0x2B
0x30
0x31
0x32
0x33
0x34
0x35
0x40
0x41
0x42
0x43
0x44
0x45
0x46
0x47
0x48
0x49
0x4A
0x4B
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Only
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Product number
Software number
Hardware number
System flags
Global events
ProxFusion UI flags
Device information data
SAR and metal UI flags
Metal detect UI output 0
Metal detect UI output 1
Hall-effect UI flags
Flags and user interface data
Hall-effect UI output 0
Hall-effect UI output 1
Temperature UI flags
Temperature UI output 0
Temperature UI output 1
Channel 0 counts low
Channel 0 counts high
Channel 1 counts low
Channel 1 counts high
Channel 2 counts low
Channel 2 counts high
Channel 3 counts low
Channel 3 counts high
Channel 4 counts low
Channel 4 counts high
Channel 5 counts low
Channel 5 counts high
Channel 0 LTA low
Channel counts (raw data)
Channel 0 LTA high
Channel 1 LTA low
Channel 1 LTA high
Channel 2 LTA low
LTA values (filtered data)
Channel 2 LTA high
ProxFusion settings 0_0
ProxFusion settings 0_1
ProxFusion settings 0_2
ProxFusion settings 1_0
ProxFusion settings 1_1
ProxFusion settings 1_2
ProxFusion settings 2_0
ProxFusion settings 2_1
ProxFusion settings 2_2
ProxFusion settings 3_0
ProxFusion settings 3_1
ProxFusion settings 3_2
ProxFusion sensor settings
block 0
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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November 2016
IQ Switch
ProxFusion Series
0x50
0x51
0x52
0x53
0x54
0x55
0x56
0x57
0x60
0x61
0x62
0x63
0x64
0x65
0x66
0x70
0x71
0x72
0x73
0x74
0x75
0x80
0x81
0x82
0x83
0x90
0x91
0x92
0x93
0xA0
0xA1
0xA2
0xC0
0xC1
0xC2
0xC3
0xD0
0xD1
0xD2
0xD3
0xD4
0xD5
0xD6
0xD7
0xD8
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
Read-Write
ProxFusion settings 4
ProxFusion settings 5
Compensation Ch0
Compensation Ch1
Compensation Ch2
ProxFusion sensor settings
block 1
Multipliers Ch0
Multipliers Ch1
Multipliers Ch2
Prox threshold Ch0
Touch threshold Ch0
Prox threshold Ch1
Touch threshold Ch1
Prox threshold Ch2
ProxFusion UI settings
Touch threshold Ch2
ProxFusion discrete UI halt time
SAR UI settings 0
SAR UI settings 1
QRD threshold Ch0
Filter halt threshold Ch0
Prox threshold Ch0
SAR UI settings
Quick release detection halt time
Metal detect UI settings
Metal detect UI filter halt threshold
Metal detect UI prox threshold
Metal detect UI touch threshold
Hall-effect settings 0
Metal detect UI settings
Hall-effect settings 1
Hall-effect sensor settings
Hall-effect switch UI settings
Temperature UI settings
Compensation Ch4 and Ch5
Multipliers Ch4 and Ch5
Hall-effect switch UI settings
Hall-effect switch UI prox threshold
Hall-effect switch UI touch threshold
Temperature UI settings
Multipliers Ch3
Temperature calibration data0
Temperature calibration data1
System settings
Active channels
Power mode settings
Normal mode report rate
Low power mode report rate
Ultra-low power mode report rate
Auto mode time
Device and power mode
settings
Global event mask
PWM control
Copyright © Azoteq 2016
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IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 25 of 63
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IQ Switch
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8.2 Device Information Data
8.2.1 Product number
Product number (0x00)
Bit
7
6
5
4
3
2
1
0
Number
Data
Access
R
R
R
R
R
R
R
R
Name
Device Product Number
Bit definitions:
Bit 7-0: Device Product Number = D’65’
8.2.2 Software number
Software number (0x01)
Bit
Number
Data
7
6
5
4
3
2
1
0
R
R
R
R
R
R
R
R
Access
Name
Device Software Number
Bit definitions:
Bit 7-0: Device Software Number = D’04’
8.2.3 Hardware number
Hardware number (0x02)
Bit
Number
Data
7
6
5
4
3
2
1
0
R
R
R
R
R
R
R
R
Access
Name
Device Hardware Number
Bit definitions:
Bit 7-0: Device Hardware Number = D’130’
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without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.3 Flags and user interface data
8.3.1 System flags
System flags (0x10)
Bit
7
6
-
5
-
4
3
2
R
1
R
0
Number
Data
R
R
R
R
Access
SHOW
RESET
NP SEG
ACTIVE
Name
-
-
POWER MODE
IN ATI
EVENT
Bit definitions:
Bit 7: Reset Indicator
o 0: No reset event
o 1: A device reset has occurred and needs to be acknowledged.
Bit 4-3: Active power-mode indicator
o 00: Normal Mode
o 01: Low Power Mode
o 10: Ultra-Low Power Mode
o 11: Halt Mode
Bit 2: ATI busy indicator
o 0: No channels are in ATI
o 1: One or more channels are in ATI
Bit 1: Global Event Indicator
o 0: No new event to service
o 1: An event has occurred and should be serviced
Bit 0: Normal power segment indicator
o 0: Not performing a normal power update
o 1: Busy performing a normal power update
8.3.2 Global events
Global events (0x11)
Bit
7
6
R
5
R
4
R
3
R
2
R
1
0
Number
Data
R
R
R
Access
PROX
SENSE
EVENT
SAR
Name
PMU
SYS
TEMP
METAL
HALL
SAR
EVENT
ACTIVE
EVENT EVENT EVENT DETECT EVENT
Bit definitions:
Bit 7: SAR activation state
o 0: SAR output inactive
o 1: SAR output active
Bit 6: Power management unit event flag
o 0: No event to report
o 1: A power management event occurred
Bit 5: System event flag
o 0: No event to report
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IQ Switch
ProxFusion Series
o 1: A system event has occurred and should be handled
Bit 4: Temperature event flag
o 0: No event to report
o 1: A temperature event has occurred and should be handled
Bit 4: Metal detect event flag
o 0: No event to report
o 1: A metal detect event has occurred and should be handled
Bit 2: Hall-effect event flag
o 0: No event to report
o 1: A Hall-effect event has occurred and should be handled
Bit 1: SAR event flag
o 0: No event to report
o 1: A SAR event has occurred and should be handled
Bit 0: ProxSense event flag
o 0: No event to report
o 1: A capacitive key event has occurred and should be handled
8.3.3 ProxFusion UI flags
ProxFusion UI flags (0x12)
Bit
Number
Data
Access
Name
7
6
5
4
3
2
1
0
-
-
R
R
R
-
-
R
R
R
CH2_T
CH1_T
CH0_T
CH2_P
CH1_P
CH0_P
Bit definitions:
Bit 6: Ch2 touch indicator
o 0: Delta below touch level
o 1: Delta above touch level
Bit 5: Ch1 touch indicator
o 0: Delta below touch level
o 1: Delta above touch level
Bit 4: Ch0 touch indicator
o 0: Delta below touch level
o 1: Delta above touch level
Bit 2: Ch2 proximity indicator
o 0: Delta below proximity level
o 1: Delta above proximity level
Bit 1: Ch1 proximity indicator
o 0: Delta below proximity level
o 1: Delta above proximity level
Bit 0: Ch0 proximity indicator
o 0: Delta below proximity level
o 1: Delta above proximity level
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.3.4 SAR UI flags
SAR UI flags (0x13)
Bit
7
6
-
5
-
4
3
-
2
R
1
0
R
Number
Data
-
R
R
Access
SAR
ACTIVE
MOVE-
MENT
Name
-
-
-
QRD
FHALT
Bit definitions:
Bit 4: SAR Standoff Active
o 0: Delta below SAR threshold level
o 1: Delta above SAR threshold level
Bit 2: Quick Release Detection (QRD) indicator
o 0: Quick release not detected
o 1: Quick release detected
Bit 1: Movement indicator
o 0: Movement not detected
o 1: Movement detected
Bit 0: Filter Halt indicator
o 0: Delta below filter halt level
o 1: Delta above filter halt level
8.3.5 Metal detect UI flags
Metal detect UI flags (0x13)
Bit
Number
Data
7
6
R
5
R
4
-
3
-
2
-
1
-
0
-
R
Access
Signed
output
Name
TOUCH
PROX
-
-
-
-
-
Bit definitions:
Bit 7: Delta directional signed output
o 0: Counts rise above the LTA
o 1: Counts fall below the LTA
Bit 6: Metal detect touch indicator
o 0: Delta below touch level
o 1: Delta above touch level
Bit 5: Metal detect proximity indicator
o 0: Delta below proximity level
o 1: Delta above proximity level
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without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.3.6 Metal detect UI output
Metal detect UI output (0x14 - 0x15)
Bit
Number
Data
Access
Name
Bit
Number
Data
7
6
5
4
3
2
1
0
R
R
R
R
R
R
R
R
Metal Detect UI Output Low Byte
15
R
14
R
13
R
12
R
11
R
10
R
9
8
R
R
Access
Name
Metal Detect UI Output High Byte
Bit definitions:
Bit 15-0: Metal Detect UI output value
8.3.7 Hall-effect UI flags
Hall-effect UI flags (0x16)
Bit
Number
Data
7
-
6
-
5
-
4
-
3
-
2
R
1
0
R
R
Access
HALL
N/S
Name
-
-
-
-
-
TOUCH
PROX
Bit definitions:
Bit 2: Hall-effect touch indicator
o 0: Field strength below touch level
o 1: Field strength above touch level
Bit 1: Hall-effect proximity indicator
o 0: Field strength below proximity level
o 1: Field strength above proximity level
Bit 0: Hall-effect North South Field indication
o 0: North field present
o 1: South field present
8.3.8 Hall-effect UI output
Hall-effect UI output (0x17/0x18)
Bit
Number
Data
7
6
5
4
3
2
1
0
R
R
R
R
R
R
R
R
Access
Name
Hall-effect UI Output Low Byte
Bit
Number
Data
Access
15
R
14
R
13
R
12
R
11
R
10
R
9
8
R
R
Name
Hall-effect UI Output High Byte
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
Bit definitions:
Bit 15-0: Hall-effect UI output
o 0 – 8 000: Hall-effect UI output value
8.3.9 Temperature UI flags
Temperature UI flags (0x19)
Bit
Number
Data
Access
7
6
-
5
-
4
-
3
-
2
-
1
-
0
-
R
Temp
trip
Name
-
-
-
-
-
-
-
Bit definitions:
Bit 7: Temperature trip indicator
o 0: No event to report
o 1: Temperature reseed event occurred
8.3.10 Temperature UI output
Temperature UI output (0x1A – 0x1B)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R
R
R
R
R
R
R
R
Name
Temperature output low byte
Bit
Number
Data
Access
15
R
14
R
13
R
12
R
11
R
10
R
9
8
R
R
Name
Temperature output high byte
Bit definitions:
Bit 15-0: Temperature UI output
o Integer value: Temperature output value in units of Kelvin (K)
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without any warranty and are subject to change without notice.
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IQ Switch
ProxFusion Series
8.4 Channel counts (raw data)
Channel counts Ch0/1/2/3 (0x20/0x21 - 0x26/0x27)
Bit
Number
Data
Access
Name
Bit
Number
Data
7
6
5
4
3
2
1
0
R
R
R
R
R
R
R
R
Channel Data Low Byte
15
R
14
R
13
R
12
R
11
R
10
R
9
8
R
R
Access
Name
Channel Data High Byte
Bit definitions:
Bit 0-15: AC filtered or raw value counts
Channel counts Ch4/5 (0x28/0x29 - 0x2A/0x2B)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R
R
R
R
R
R
R
R
Name
Bit
Number
Data
Channel Data Low Byte
15
R
14
R
13
R
12
R
11
R
10
R
9
8
R
R
Access
Name
Channel Data High Byte
Bit definitions:
Bit 0-15: AC filtered or raw value counts of Hall-effect sensors channels
8.5 LTA values (filtered data)
LTA Ch0/1/2 (0x30/0x31 - 0x34/0x35)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R
R
R
R
R
R
R
R
Name
LTA Low Byte
Bit
Number
Data
Access
15
R
14
R
13
R
12
R
11
R
10
R
9
8
R
R
Name
LTA High Byte
Bit definitions:
Bit 0-15: LTA filter value output
Copyright © Azoteq 2016
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IQS620 Preliminary pre-production datasheet revision 0.91
Page 32 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.6 ProxFusion sensor settings block 0
8.6.1 ProxFusion settings 0
8.6.1.1 Capacitive sensing
ProxFusion settings 0_0/1/2 (0x40-0x42)
Bit
Number
Data
Access
7
6
5
-
4
-
3
-
2
-
1
0
R/W
R/W
R/W
R/W
Capacitive sensor
mode
Internal
use
Internal
use
Name
-
-
RX Select
Fixed
value
0
0
Bit definitions:
Bit 7-6: Sensor Mode
o 00: Capacitive sensing mode
Bit 1-0: RX Select
o 00: RX 0 and RX is disabled
o 01: RX 0 is enabled
o 10: RX 1 is enabled
o 11: RX 0 and RX 1 is enabled
8.6.1.2 Inductive sensing
ProxFusion settings 0_0/1/2 (0x40-0x42)
Bit
Number
Data
7
6
5
-
4
3
-
2
-
1
0
R/W
R/W
R/W
R/W
R/W
Access
Inductive sensor
mode
Internal Multiplier
use range
Name
-
-
RX Select
Fixed
value
1
0
1
1
Bit definitions:
Bit 7-6: Sensor Mode
o 10: Inductive sensor mode
Bit 4: Multiplier range
o 0: Small
o 1: Large
Bit 1-0: RX Select
o 11: RX 0 and RX 1 is enabled
Copyright © Azoteq 2016
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IQS620 Preliminary pre-production datasheet revision 0.91
Page 33 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.6.2 ProxFusion settings 1
8.6.2.1 Capacitive sensing
ProxFusion settings 1_0/1/2 (0x43 - 0x45)
Bit
Number
Data
Access
7
6
5
4
3
-
2
-
1
0
-
-
R/W
CSz
R/W
R/W
R/W
R/W
Name
CHARGE FREQ
-
AUTO ATI MODE
Bit definitions:
Bit 6: CS size
o 0: CS capacitor size is 15 pF
o 1: CS capacitor size is 60 pF
Bit 5-4: Charge frequency divider
o 00: 1/2
o 01: 1/4
o 10: 1/8
o 11: 1/16
Bit 1-0: Auto ATI Mode
o 00: ATI disabled
o 01: Partial ATI (all multipliers are fixed)
o 10: Semi-Partial ATI (only coarse multipliers are fixed)
o 11: Full-ATI
8.6.2.2 Inductive sensing
Bit
ProxFusion settings 1_0/1/2 (0x43 - 0x45)
7
6
5
4
3
-
2
-
1
0
Number
Data
Access
Name
-
-
R/W
CSz
R/W
R/W
R/W
R/W
CHARGE FREQ
-
AUTO ATI MODE
Bit definitions:
Bit 6: CS size
o 0: CS capacitor size is 15 pF
o 1: CS capacitor size is 60 pF
Bit 5-4: Charge frequency divider
o 00: 1/2
o 01: 1/4
o 10: 1/8
o 11: 1/16
Bit 1-0: Auto ATI Mode
o 00: ATI disabled
o 01: Partial ATI (all multipliers are fixed)
o 10: Semi-Partial ATI (only coarse multipliers are fixed)
o 11: Full-ATI
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 34 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.6.3 ProxFusion settings 2
8.6.3.1 Capacitive sensing
ProxFusion settings 2_0/1/2 (0x46 - 0x48)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
ATI_BASE
ATI_TARGET (x32)
Bit definitions:
Bit 7-6: Auto ATI base value
o 00: 75
o 01: 100
o 10: 150
o 11: 200
Bit 5-0: Auto ATI Target
o ATI Target is 6-bit value x 32
8.6.3.2 Inductive sensing
ProxFusion settings 2_0/1/2 (0x46 - 0x48)
Bit
7
6
5
4
3
2
1
0
Number
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
ATI_BASE
ATI_TARGET (x32)
Bit definitions:
Bit 7-6: Auto ATI base value
o 00: 75
o 01: 100
o 10: 150
o 11: 200
Bit 5-0: Auto ATI Target
o ATI Target is 6-bit value x 32
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 35 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.6.4 ProxFusion settings 3
8.6.4.1 Capacitive sensing
ProxFusion settings 3_0/1/2 (0x49 - 0x4B)
Bit
Number
Data
Access
7
6
5
4
-
3
2
1
0
-
R/W
R/W
R/W
R/W
R/W
R/W
Internal UP LEN
use EN
Name
UP_LENGTH
CS DIV
PASS_LENGTH
-
Bit definitions:
Bit 7-6: Up length select (requires UP_LENGTH_EN = 1 for use)
o 00: Up length = 0010
o 01: Up length = 0110
o 10: Up length = 1010
o 11: Up length = 1110
Bit 5: CS divider
o 0: Normal CS cap size
o 1: CS cap size 5 times smaller
Bit 3: Up length select enable
o 0: Up length select is disabled
o 1: Up length select is enabled (value in bit 7-6 is used)
Bit 2-1: Pass length select
o 00: Pass length = 001
o 01: Pass length = 011
o 10: Pass length = 101
o 11: Pass length = 111
8.6.4.2 Inductive sensing
ProxFusion settings 3_0/1/2 (0x49 - 0x4B)
Bit
Number
Data
7
-
6
5
4
-
3
2
-
1
-
0
-
-
R/W
R/W
Access
Internal UP LEN
use EN
Name
-
CS DIV
-
-
Bit definitions:
Bit 5: CS divider
o 0: Normal CS cap size
o 1: CS cap size 3 times smaller
Copyright © Azoteq 2016
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IQS620 Preliminary pre-production datasheet revision 0.91
Page 36 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.7 ProxFusion sensor settings block 1
8.7.1 ProxFusion settings 4
8.7.1.1 Capacitive sensing
ProxFusion settings 4 (0x50)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
TWO
SIDED
EN
Internal
use
ACF
DISABLE
Name
SAR EN
LTA BETA
ACF BETA
Bit definitions:
Bit 7: SAR UI enable
o 0: SAR UI is disabled
o 1: SAR UI is enabled
Bit 5: Two sided detection
o 0: Bidirectional detection disabled
o 1: Bidirectional detection enabled
Bit 4: Disable AC filter
o 0: AC filter enabled
o 1: AC filter disabled
Bit 3-2: Long term average beta value
o 00: 7
o 01: 8
o 10: 9
o 11: 10
Bit 1-0: AC filter beta value
o 00: 1
o 01: 2
o 10: 3
o 11: 4
8.7.1.2 Inductive sensing
ProxFusion settings 4 (0x50)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
METAL
SAR EN DETECT
EN
TWO
SIDED
EN
ACF
DISABLE
Name
LTA BETA
ACF BETA
Bit definitions:
Bit 7: SAR UI enable
o 0: SAR UI is disabled
o 1: SAR UI is enabled
Bit 6: Metal detection UI enable
Copyright © Azoteq 2016
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IQS620 Preliminary pre-production datasheet revision 0.91
Page 37 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
o 0: Metal detection UI is disabled
o 1: Metal detection UI is enabled
Bit 5: Two sided detection
o 0: Bidirectional detection disabled
o 1: Bidirectional detection enabled
Bit 4: Disable AC filter
o 0: AC filter enabled
o 1: AC filter disabled
Bit 3-2: Long term average beta value
o 00: 7
o 01: 8
o 10: 9
o 11: 10
Bit 1-0: AC filter beta value
o 00: 1
o 01: 2
o 10: 3
o 11: 4
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 38 of 63
November 2016
IQ Switch
ProxFusion Series
8.7.2 ProxFusion settings 5
Bit
ProxFusion settings 5 (0x51)
7
6
5
-
4
-
3
-
2
-
1
-
0
-
Number
Data
R/W
-
Access
Disable
Ch1 auto
Name
Internal use
Bit definitions:
Bit7: Disable Ch1 auto
o 0: Ch1 is enabled when SAR UI is active
o 1: Ch1 is disabled when SAR UI is active
Bit 6-0: Internal use
8.7.3 Compensation
Compensation Ch0/1/2 (0x52 - 0x54)
Bit
7
6
5
4
3
2
1
0
Number
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
Compensation (0-7)
Bit definitions:
Bit 7-0: Compensation (7-0)
o 0-255: Lower 8-bits of the Compensation value.
8.7.4 Multipliers
Multipliers Ch0/1/2 (0x55-0x57)
Bit
7
6
5
4
3
2
1
0
Number
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
Compensation (8-9)
Multiplier coarse
Multiplier fine
Bit definitions:
Bit 7-6: Compensation (8-9)
o 0-3: Upper 2-bits of the Compensation value.
Bit 5-4: Multiplier coarse
o 0-3: Coarse multiplier selection
Bit 3-0: Multiplier fine
o 0-15: Fine multiplier selection
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 39 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.8 ProxFusion UI settings
8.8.1 Prox threshold Ch0/1/2
Prox threshold Ch0/1/2 (0x60/0x62/0x64)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
Proximity threshold value
Bit definitions:
Bit 7-0: Proximity threshold = Proximity threshold value
8.8.2 Touch threshold Ch0/1/2
Touch threshold Ch0/1/2 (0x61/0x63/0x65)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
Touch threshold value
Bit definitions:
Bit 7-0: Touch threshold = Touch threshold value * LTA/ 256
8.8.3 ProxFusion discrete UI halt time
ProxFusion discrete UI halt time (0x66)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
Halt Time
Bit definitions:
Bit 7-0: Halt time in 500ms increments (decimal value x 500ms)
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 40 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.9 SAR UI settings
8.9.1 SAR UI settings 0
SAR UI settings 0 (0x70)
Bit
Number
Data
7
-
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
SAR To
GPIO0
Name
-
QRD Beta
Movement Beta
Bit definitions:
Bit 6-4: Quick Release Detection Beta
o 0-7: quick release filter beta value
Bit 3: SAR Standoff State To GPIO0
o 0: SAR standoff state to GPIO0 not active. RDY on GPIO0
o 1: SAR standoff state to GPIO0 active. No RDY signal
Bit 2-0: Movement Detection Filter Beta
o 0-7: Movement filter beta value
8.9.2 SAR UI settings 1
SAR UI settings 1 (0x71)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
LTA Halt timeout in no Prox
Movement detection Threshold
Bit definitions:
Bit 7-4: LTA Halt timeout in no Prox
o 0-15: LTA Halt timeout in no Prox in 500 ms ticks
Bit 3-0: Movement Detection Threshold
o 0-15: Movement Threshold = Movement Threshold Value
8.9.3 Quick release detection threshold
Quick release detection threshold (0x72)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
QRD Threshold value
Bit definitions:
Bit 7-0: Proximity Threshold = Proximity Threshold Value
Copyright © Azoteq 2016
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IQS620 Preliminary pre-production datasheet revision 0.91
Page 41 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.9.4 Filter halt threshold
Bit
Filter halt threshold (0x73)
7
6
5
4
3
2
1
0
Number
Data
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
Filter Halt Threshold value
Bit definitions:
Bit 7-0: Filter Halt Threshold = Filter Halt Threshold Value
8.9.5 Proximity threshold
Proximity threshold (0x74)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
Proximity Threshold value
Bit definitions:
Bit 7-0: Proximity Threshold = Proximity Threshold Value
8.9.6 Quick release detection halt time
Quick release detection halt time (0x75)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
LTA halt timeout after a QRD (decimal value x 500ms)
Bit definitions:
Bit 7-0: LTA halt timeout after a Quick release detection with no movement afterwards
(decimal value x 500 ms)
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 42 of 63
November 2016
IQ Switch
ProxFusion Series
8.10Metal detection UI settings
8.10.1 Metal detect UI settings
Metal detect UI settings (0x80)
Bit
Number
Data
Access
Name
7
6
5
4
3
2
1
0
-
-
-
-
R/W
R/W
-
-
-
-
R/W
R/W
Hysteresis T
Hysteresis P
Bit definitions:
Bit 5-4: Touch hysteresis
o 00: Disabled
o 01: 1/4 of threshold
o 10: 1/8 of threshold
o 11: 1/16 of threshold
Bit 1-0: Proximity hysteresis
o 00: Disabled
o 01: 1/4 of threshold
o 10: 1/8 of threshold
o 11: 1/16 of threshold
8.10.2 Metal detect UI filter halt threshold
Metal detect UI filter halt threshold (0x81)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
Metal detect filter halt threshold value
Bit definitions:
Bit 7-0: Filter halt threshold = Filter halt threshold value
8.10.3 Metal detect UI proximity threshold
Metal detect UI proximity threshold (0x82)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
Proximity threshold value
Bit definitions:
Bit 7-0: Proximity threshold = Proximity threshold value
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 43 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.10.4 Metal detect UI touch threshold
Metal detect UI touch threshold (0x83)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
Touch threshold value
Bit definitions:
Bit 7-0: Touch threshold = Touch threshold value * 4
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 44 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.11Hall-effect sensor settings
8.11.1 Hall-effect settings 0
Hall-effect settings 0 (0x90)
Bit
Number
Data
Access
Name
7
6
5
4
3
-
2
-
1
0
-
-
-
-
R/W
R/W
R/W
R/W
CHARGE FREQ
reserved
AUTO ATI MODE
Bit definitions:
Bit 5-4: Charge frequency divider
o 00: 1/2
o 01: 1/4
o 10: 1/8
o 11: 1/16
Bit 1-0: Auto ATI Mode
o 00: ATI disabled
o 01: Partial ATI (all multipliers are fixed)
o 10: Semi-Partial ATI (only coarse multipliers are fixed)
o 11: Full-ATI
8.11.2 Hall-effect settings 1
Hall-effect settings 1 (0x91)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
ATI_BASE
ATI_TARGET (x32)
Bit definitions:
Bit 7-6: Auto ATI base value
o 00: 75
o 01: 100
o 10: 150
o 11: 200
Bit 5-0: Auto ATI Target
o ATI Target is 6-bit value x 32
8.11.3 Compensation Ch4/5
Compensation Ch4/5 (0x92)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
Compensation (7-0)
Bit definitions:
Bit 7-0: Compensation (7-0)
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 45 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
o 7-0: Lower 8-bits of the Compensation value.
8.11.4 Multipliers Ch4/5
Multipliers Ch4/5 (0x93)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
Compensation (9-8)
Multipliers coarse
Multipliers fine
Bit definitions:
Bit 7-6: Compensation (9-8)
o 0-3: Upper 2-bits of the Compensation value.
Bit 5-4: Multipliers coarse
o 0-3: Coarse multiplier selection
Bit 3-0: Multipliers fine
o 0-15: Fine multiplier selection
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Page 46 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.12Hall-effect switch UI settings
8.12.1 Hall-effect switch UI settings
Hall-effect switch UI settings (0xA0)
Bit
Number
Data
Access
Name
7
6
5
4
3
2
1
0
-
-
R/W
R/W
R/W
-
-
R/W
R/W
R/W
Lin Mode
Hysteresis T
Swap Dir
Hysteresis P
Bit definitions:
Bit 6: Linearize Output
o 0: Disabled
o 1: Enabled
Bit 5-4: Touch Hysteresis
o 00: Disabled
o 01: 1/4 of threshold
o 10: 1/8 of threshold
o 11: 1/16 of threshold
Bit 2: Swap field direction indication
o 0: Disabled
o 1: Enabled
Bit 1-0: Proximity Hysteresis
o 00: Disabled
o 01: 1/4 of threshold
o 10: 1/8 of threshold
o 11: 1/16 of threshold
8.12.2 Hall-effect switch UI proximity threshold
Hall-effect switch UI proximity threshold (0xA1)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
Proximity Threshold Value
Bit definitions:
Bit 7-0: Proximity Threshold = Proximity Threshold Value
8.12.3 Hall-effect switch UI touch threshold
Hall-effect switch UI touch threshold (0xA2)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
Touch Threshold Value
Bit definitions:
Bit 7-0: Touch Threshold = Touch Threshold Value * 4
Copyright © Azoteq 2016
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IQS620 Preliminary pre-production datasheet revision 0.91
Page 47 of 63
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.13Temperature UI settings
8.13.1 Temperature UI settings
Temperature UI settings (0xC0)
Bit
Number
Data
7
-
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Reseed Reseed
in prox enable
Name
-
Reseed threshold
Bit definitions:
Bit 6: Reseed in prox
o 0: Reseed will not occur during a prox
o 1: Reseed will occur during a prox
Bit 5: Reseed enable
o 0: Disabled
o 1: Enabled
Bit 4-0: Reseed threshold
o 0 - 32: Reseed threshold = Reseed threshold value
8.13.2 Ch3 Multipliers
Multipliers Ch3 (0xC1)
Bit
7
6
5
4
3
2
1
0
Number
Data
Access
Name
-
-
-
R/W
R/W
R/W
R/W
R/W
R/W
-
Multiplier coarse
Multiplier fine
Bit definitions:
Bit 5-4: Multiplier coarse
o 0-3: Coarse multiplier selection
Bit 3-0: Multiplier fine
o 0-15: Fine multiplier selection
8.13.3 Temperature calibration data
Temperature calibration data0 (0xC2)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
Name
R/W
Temperature multiplier
R/W
Temperature divider
Bit definitions:
Bit 7-4: Temperature multiplier
o 0 – 16: Temperature multiplier value
Bit 3 – 0: Temperature divider
o 0 – 16:Temeprature divider value
Copyright © Azoteq 2016
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Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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November 2016
IQ Switch
ProxFusion Series
Temperature calibration data1 (0xC3)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
Temperature offset
Bit definitions:
Bit 7-0: Temperature offset
o 0 – 255: Temperature offset value
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Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
8.14Device and power mode settings
8.14.1 System settings
System settings (0xD0)
Bit
7
6
5
4
3
2
1
0
Number
Data
Access
W=1
W=1
R/W
R/W
4MHz
R/W
R/W
W=1
W=1
SOFT
RESET
ACK
RESET
EVENT
MODE
COMMS
ATI
ATI
BAND
REDO
ATI
Name
RESEED
Bit definitions:
Bit 7: Software Reset (Set only, will clear when done)
o 1: Causes the device to perform a WDT reset
Bit 6: ACK Reset (Set only, will clear when done)
o 1: Acknowledge that a reset has occurred. This event will trigger until
acknowledged.
Bit 5: Event mode enable
o 0: Event mode disabled. Default streaming mode communication.
o 1: Event mode communication enabled.
Bit 4: Main Clock frequency selection
o 0: Run FOSC at 16MHz
o 1: Run FOSC at 4MHz
Bit 3: Communications during ATI
o 0: No communications are generated during ATI
o 1: Communication continue as setup regardless of ATI state.
Bit 2: Re-ATI Band selection
o 0: Re-ATI when outside 1/8 of ATI target
o 1: Re-ATI when outside 1/16 of ATI target
Bit 1: Redo ATI on all channels (Set only, will clear when done)
o 1: Redo the ATI on all channels
Bit 0: Reseed all Long-term filters (Set only, will clear when done)
o 1: Reseed all channels
8.14.2 Active channels
Active channels (0xD1)
Bit
7
6
5
4
3
2
1
0
Number
Data
Access
Name
-
-
-
R/W
Ch5
R/W
Ch4
R/W
Ch3
R/W
Ch2
R/W
Ch1
R/W
Ch0
-
Bit definitions:
Bit 5: Ch5 (note: Ch4 and Ch5 must both be enabled for Hall-effect switch UI to be
functional)
o 0: Channel is enabled
o 1: Channel is disabled
Bit 4: Ch4 (note: Ch4 and Ch5 must both be enabled for Hall-effect switch UI to be
functional)
Copyright © Azoteq 2016
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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November 2016
IQ Switch
ProxFusion Series
o 0: Channel is enabled
o 1: Channel is disabled
Bit 3: Ch3
o 0: Channel is enabled
o 1: Channel is disabled
Bit 2: Ch2 (note: Ch2 must be enabled for metal detect UI to be functional)
o 0: Channel is enabled
o 1: Channel is disabled
Bit 1: Ch1 (note: Ch0 and Ch1 must both be enabled for SAR UI to be functional)
o 0: Channel is disabled
o 1: Channel is enabled
Bit 0: Ch0 (note: Ch0 and Ch1 must both be enabled for SAR UI to be functional)
o 0: Channel is disabled
o 1: Channel is enabled
8.14.3 Power mode settings
Power mode settings (0xD2)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
DSBL
AUTO
MODE
PWM
OUT
EN ULP
MODE
Name
POWER MODE
NP SEG RATE
Bit definitions:
Bit 7: PWM output activation
o 0: PWM output inactive
o 1: PWM output active
Bit 6: : Allow auto ultra-low power mode switching
o 0: ULP is disabled during auto-mode switching
o 1: ULP is enabled during auto-mode switching
Bit 5: Disable auto mode switching
o 0: Auto mode switching is enabled
o 1: Auto mode switching is disabled
Bit 4-3: Manually select power mode (note: bit 5 must be set)
o 00: Normal Power mode. The device runs at the normal power rate, all enabled
channels and UIs will execute.
o 01: Low Power mode. The device runs at the low power rate, all enabled channels
and UIs will execute.
o 10: Ultra-Low Power mode. The device runs at the ultra-low power rate, Ch0 is run
as wake-up channel. The other channels execute at the NP-segment rate.
o 11: Halt Mode. No conversions are performed; the device must be removed from
this mode using an I2C command.
Bit 2-0: Normal power segment update rate
o 000: ½ ULP rate
o 001: ¼ ULP rate
Copyright © Azoteq 2016
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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November 2016
IQ Switch
ProxFusion Series
o 010: 1/8 ULP rate
o 011: 1/16 ULP rate
o 100: 1/32 ULP rate
o 101: 1/64 ULP rate
o 110: 1/128 ULP rate
o 111: 1/256 ULP rate
8.14.4 Normal power mode report rate
Normal power mode report rate (0xD3)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
Normal power mode report rate in ms
Bit definitions:
Bit 7-0: Normal mode report rate in ms (note: LPOSC timer has +- 4 ms accuracy)
8.14.5 Low power mode report rate
Low power mode report rate (0xD4)
Bit
Number
Data
7
6
5
4
3
2
1
0
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Access
Name
Low power mode report rate in ms
Bit definitions:
Bit 7-0: Low-power mode report rate in ms (note: LPOSC timer has +- 4 ms accuracy)
8.14.6 Ultra-low power mode report rate
Ultra-low power mode report rate (0xD5)
Bit
Number
7
6
5
4
3
2
1
0
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
Ultra-low power mode report rate in 16 ms increments
Bit definitions:
Bit 7-0: Ultra-low power mode report rate in 16 ms increments (decimal value x 16ms)
8.14.7 Auto mode timer
Auto mode timer (0xD6)
Bit
7
6
5
4
3
2
1
0
Number
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
Auto mode timer in 500 ms increments
Bit definitions:
Bit 7-0: Auto modes switching time in 500 ms increments (decimal value x 500ms)
Copyright © Azoteq 2016
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Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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November 2016
IQ Switch
ProxFusion Series
8.14.8 Global event mask
Bit
Global event mask (0xD7)
7
6
5
4
3
2
1
0
Number
Data
Access
R/W
SAR
R/W
PMU
R/W
SYS
R/W
R/W
R/W
HALL
R/W
R/W
PROX
SENSE
EVENT
TEMP
METAL
SAR
EVENT
Name
ACTIVE EVENT EVENT EVENT DETECT EVENT
Bit definitions:
Bit 7: SAR activation state mask
o 0: Event is allowed
o 1: Event is masked
Bit 6: Power management unit event mask
o 0: Event is allowed
o 1: Event is masked
Bit 5: System event mask
o 0: Event is allowed
o 1: Event is masked
Bit 4: Temperature event mask
o 0: Event is allowed
o 1: Event is masked
Bit 4: Metal detect event mask
o 0: Event is allowed
o 1: Event is masked
Bit 2: Hall-effect event mask
o 0: Event is allowed
o 1: Event is masked
Bit 1: SAR event mask
o 0: Event is allowed
o 1: Event is masked
Bit 0: ProxSense event mask
o 0: Event is allowed
o 1: Event is masked
8.14.9 PWM duty cycle
PWM duty cycle (0xD8)
Bit
7
6
5
4
3
2
1
0
Number
Data
Access
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
Name
PWM duty cycle (%)
Bit definitions:
Bit 7-0: PWM duty cycle (%)
o 0-100: PWM duty cycle of the fixed 1kHz PWM output available on GPIO3
Copyright © Azoteq 2016
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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IQ Switch
ProxFusion Series
9 Electrical characteristics
9.1 Absolute Maximum Specifications
The following absolute maximum parameters are specified for the device:
Exceeding these maximum specifications may cause damage to the device.
Table 9.1
Absolute maximum specification
Absolute maximum
-40°C to 85°C
Parameter
Operating temperature
Supply Voltage (VDDHI – GND)
Maximum pin voltage
3.6V
VDDHI + 0.5V (may not exceed VDDHI max)
Maximum continuous current (for specific Pins) 10mA
Minimum pin voltage
Minimum power-on slope
ESD protection
GND - 0.5V
100V/s
±4kV (Human body model)
9.2 Power On-reset/Brown out
Table 9.2
Power on-reset and brown out detection specifications
DESCRIPTION
Power On Reset
Conditions
PARAMETER
MIN
MAX
UNIT
VDDHI Slope ≥ 100V/s @25°C
POR
BOD
TBC
TBC
TBC
TBC
V
V
Brown Out Detect VDDHI Slope ≥ 100V/s @25°C
9.3 Digital input/output trigger levels
Table 9.3
Digital input/output trigger level specifications
DESCRIPTION
Conditions PARAMETER
MIN
TYPICAL
MAX
UNIT
All digital inputs
All digital inputs
All digital inputs
All digital inputs
VDD = 1.8V Input low level voltage
VDD = 1.8V Input high level voltage
VDD = 3.3V Input low level voltage
VDD = 3.3V Input high level voltage
TBC
TBC
TBC
TBC
TBC
TBC
TBC
TBC
TBC
TBC
TBC
TBC
V
V
V
V
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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IQ Switch
ProxFusion Series
9.4 Current consumptions
9.4.1 Capacitive sensing alone
Table 9.4
Capacitive sensing current consumption
Power
mode
Supply
voltage
ATI target
(counts)
Report
rate (ms)
MIN
TYPICAL
MAX
UNIT
VDD = 1.8V
10
10
-
-
-
-
-
-
-
-
-
-
-
-
TBC
26.42
17.5
5.2
-
-
-
-
-
-
-
-
-
-
-
-
NP mode
LP mode
ULP mode
Halt mode
VDD = 3.3V
512
20
100
VDD = 1.8V
VDD = 3.3V
VDD = 1.8V
TBC
TBC
TBC
3.15
3.05
TBC
TBC
TBC
A
128
240
800
VDD = 3.3V
512
VDD = 1.8V
VDD = 3.3V
9.4.2 Capacitive sensing with SAR UI active
Table 9.5 Capacitive sensing and SAR UI current consumption
Power
mode
Supply
voltage
ATI target
(counts)
Report
rate (ms)
MIN
TYPICAL
MAX
UNIT
VDD = 1.8V
10
10
-
-
-
-
-
-
-
-
-
-
-
-
-
TBC
27.8
18.03
12.25
5.35
TBC
TBC
TBC
3.15
3.05
TBC
TBC
TBC
-
-
-
-
-
-
-
-
-
-
-
-
-
NP mode
20
VDD = 3.3V
512
512
30
100
VDD = 1.8V
VDD = 3.3V
VDD = 1.8V
LP mode
A
128
240
800
ULP mode
Halt mode
VDD = 3.3V
VDD = 1.8V
VDD = 3.3V
Copyright © Azoteq 2016
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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IQ Switch
ProxFusion Series
9.4.3 Hall-effect sensing alone
Table 9.6
Hall-effect current consumption
Power
mode
Supply
voltage
ATI target
(counts)
Report rate
MIN
TYPICAL
MAX
UNIT
VDD = 1.8V
-
-
-
-
-
-
-
-
-
-
-
-
TBC
64.13
40.51
10.02
TBC
TBC
TBC
4.08
3.03
2.32
TBC
TBC
-
-
-
-
-
-
-
-
-
-
-
-
10
20
NP mode
LP mode
ULP mode
Halt mode
VDD = 3.3V
512
512
100
VDD = 1.8V
VDD = 3.3V
VDD = 1.8V
A
80
VDD = 3.3V
400
800
VDD = 1.8V
VDD = 3.3V
9.4.4 Inductive sensing alone
Table 9.7
Inductive sensing current consumption
Power
mode
Supply
voltage
ATI target
(counts)
Report rate
MIN
TYPICAL
MAX
UNIT
VDD = 1.8V
-
-
-
-
-
-
-
-
-
-
TBC
47.47
30.27
7.88
TBC
TBC
TBC
TBC
TBC
TBC
-
-
-
-
-
-
-
-
-
-
10
20
NP mode
VDD = 3.3V
512
100
VDD = 1.8V
VDD = 3.3V
VDD = 1.8V
VDD = 3.3V
VDD = 1.8V
VDD = 3.3V
LP mode
A
ULP mode
Halt mode
Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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IQ Switch
ProxFusion Series
9.5 Capacitive loading limits
To be completed.
9.6 Hall-effect measurement limits
To be completed.
9.7 Inductive measurement limits
To be completed.
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Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
10 Package information
10.1DFN10 package and footprint specifications
Table 10.1 DFN-10 Package
dimensions (bottom)
A
B
D
Dimension
[mm]
A
B
C
D
F
3 ±0.1
0.5
0.25
n/a
3 ±0.1
0.4
L
P
Q
2.4
1.65
C
P
Figure 10.1 DFN-10 Package dimensions
(bottom view). Note that the saddle needs
to be connected to common GND on the
PCB.
Table 10.2 DFN-10 Package
dimensions (side)
Dimension
[mm]
G
H
I
0.05
0.65
0.7-0.8
Figure 10.2 DFN-10 Package dimensions
(side view)
Package
outline
Table 10.3 DFN-10 Landing
dimensions
C
E
Dimension
[mm]
A
B
C
D
E
F
2.4
1.65
0.8
0.5
0.3
A
D
3.2
B
F
Figure 10.3 DFN-10 Landing pad
dimensions (top view)
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
10.2Device marking (subjected to change for production)
10.2.1 Top Marking
A
B
C
D
E
F
DEVICE NAME
REVISION
A
B
C
D
E
F
=
IQS620
=
=
=
=
=
x (IC Revision Number)
t (i = Industrial, -40°C to 85°C)
P (Internal use)
TEMPERATURE RANGE
DATE CODE
WWYY (Batch number)
Dot to indicate pin 1
PIN 1 MARKING
10.3Ordering Information
Order quantities will be subject to multiples of a full reel. Contact the official distributor for sample
quantities. A list of the distributors can be found under the “Distributors” section of
www.azoteq.com.
IQS620 z ppb
IC NAME
BULK PACKAGING
PACKAGING TYPE
SUB ADDRESS
CONFIGURATION
IC NAME
IQS620
z
=
=
IQS620
CONFIGURATION
Sub Address Configuration (hexadecimal)
0 = 44H
1 = 45H
2 = 46H
3 = 47H
4 = 4CH
5 = 4DH
6 = 4EH
7 = 4FH
PACKAGE TYPE
DN
R
=
=
DFN10 (3x3)
BULK PACKAGING
Reel DNF10 (3x3) – 3000pcs/reel
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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November 2016
IQ Switch
ProxFusion Series
10.4Tape and reel specification
Copyright © Azoteq 2016
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IQS620 Preliminary pre-production datasheet revision 0.91
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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IQ Switch
ProxFusion Series
10.5MSL Level
Moisture Sensitivity Level (MSL) relates to the packaging and handling precautions for some
semiconductors. The MSL is an electronic standard for the time period in which a moisture sensitive
device can be exposed to ambient room conditions (approximately 30°C / 85%RH see J-STD033C
for more info) before reflow occur.
Package
Level (duration)
MSL 1 (Unlimited at ≤30°C / 85% RH)
Reflow profile peak temperature < 260°C for < 30 seconds
DFN10
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
November 2016
IQ Switch
ProxFusion Series
11 Datasheet revisions
11.1Revision history
v1.0 – First release version
11.2Errata
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of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
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IQ Switch
ProxFusion Series
Appendix A. Contact information
USA
Asia
South Africa
Physical
Address
Rm2125, Glittery City
Shennan Rd
Futian District
Shenzhen, 518033
China
109 Main Street
Paarl
7646
6507 Jester Blvd
Bldg 5, suite 510G
Austin
TX 78750
USA
South Africa
Postal
Address
Rm2125, Glittery City
Shennan Rd
Futian District
Shenzhen, 518033
China
PO Box 3534
Paarl
7620
6507 Jester Blvd
Bldg 5, suite 510G
Austin
TX 78750
USA
South Africa
Tel
+1 512 538 1995
+1 512 672 8442
info@azoteq.com
+86 755 8303 5294
ext 808
+27 21 863 0033
+27 21 863 1512
info@azoteq.com
Fax
Email
info@azoteq.com
Please visit www.azoteq.com for a list of distributors and worldwide representation.
The following patents relate to the device or usage of the device: US 6,249,089; US 6,952,084; US 6,984,900; US
7,084,526; US 7,084,531; US 8,395,395; US 8,531,120; US 8,659,306; US 8,823,273; US 9,209,803; US 9,360,510; EP 2,351,220;
EP 2,559,164; EP 2,656,189; HK 1,156,120; HK 1,157,080; SA 2001/2151; SA 2006/05363; SA 2014/01541; SA 2015/023634
IQ Switch®, SwipeSwitch™, ProxSense®, LightSense™, AirButtonTM, ProxFusion™, Crystal Driver™ and the
logo are trademarks of Azoteq.
The information in this Datasheet is believed to be accurate at the time of publication. Azoteq uses reasonable effort to maintain the information up-to-date and accurate, but does not warrant the
accuracy, completeness or reliability of the information contained herein. All content and information are provided on an “as is” basis only, without any representations or warranties, express or
implied, of any kind, including representations about the suitability of these products or information for any purpose. Values in the datasheet is subject to change without notice, please ensure to
always use the latest version of this document. Application specific operating conditions should be taken into account during design and verified before mass production. Azoteq disclaims all
warranties and conditions with regard to these products and information, including but not limited to all implied warranties and conditions of merchantability, fitness for a particular purpose, title
and non-infringement of any third party intellectual property rights. Azoteq assumes no liability for any damages or injury arising from any use of the information or the product or caused by, without
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Copyright © Azoteq 2016
All Rights Reserved
IQS620 Preliminary pre-production datasheet revision 0.91
Information in this datasheet is based on products in the design, validation or qualification phase
of development. The performance and parameters shown in this document are preliminary
without any warranty and are subject to change without notice.
Page 63 of 63
November 2016
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