IQS213A-00000000-MSR

IQ Switch® ProxSense® Series IQS213A Datasheet IQSwitch® - ProxSense® Series 3-Channel Capacitive Touch/Swipe Function Controller Overview Unparalleled Features     Sub 5µA* current consumption (“Zero-Power” electronic switch). Internal Capacitor Implementation (ICI) – Reference capacitor on-chip Automatic Tuning Implementation (ATI) - Automatic tuning for optimal operation in various environments & compensation against sensitivity reducing objects IQS213A advised for applications with high load-capacitances and high sensitivity requirements. The IQS213A ProxSense® IC is a fully integrated two or three channel capacitive swipe function sensor with market leading sensitivity and automatic tuning of the sense electrodes. The IQS213A provides a minimalist implementation requiring few external components, with OTP-option settings (Stand-Alone mode) and programmable I2C-compatible interface, which allow configuration for numerous applications. Main Features             2 or 3 Channel (Projected- or Self-Capacitance) Input device Swipe Function or Individual (Normal) Touch Electrode Implementation Variable User Interface with Adjustable Swipe Function Configuration Auto-Off and Advanced Auto-Off Warning Function Supply voltage: 1.8V to 3.6V Internal voltage regulator and reference capacitor Advanced on-chip digital signal processing OTP (One Time Programmable) options available 2 Stand-Alone GPIO Output (Default) / I C-compatible interface Low Power Modes (sub 4µA*) Variable Proximity & Touch Thresholds Small outline MSOP-10 package Applications      Sanitary ware, toys, office equipment Flashlights, headlamps, keychain lights Splash- / waterproof devices Swipe-to-Unlock / Wake from Standby applications Replacement for electro-mechanical switches Advantages     Prevents accidental activation of conventional touch sensors Improved digital filtering to reduce external noise High immunity against aqueous substances 2 Highly adjustable device with continuous data or event driven I C communication Available options TA MSOP10 -20°C to 85°C IQS213A *Current consumption dependant on selected Low Power settings. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 1 of 48 October 2018 IQ Switch® ProxSense® Series Contents 8.6 8.7 8.8 8.9 8.10 OVERVIEW ................................................................ 1 CONTENTS ................................................................. 2 1 FUNCTIONAL OVERVIEW .................................. 3 1.1 APPLICABILITY ............................................... 3 2 ANALOGUE FUNCTIONALITY............................. 3 3 DIGITAL FUNCTIONALITY .................................. 3 4 HARDWARE CONFIGURATION .......................... 4 5 10 EVENT MODE .............................................. 30 2 I C SPECIFIC COMMANDS.............................. 30 2 I C READ AND W RITE SPECIFICS ................... 30 IQS213A MEMORY MAP ..................................31 USER CONFIGURABLE OPTIONS ........................ 7 11 ELECTRICAL SPECIFICATIONS – ALL PRELIMINARY ..........................................................41 11.1 ABSOLUTE MAXIMUM SPECIFICATIONS ........... 41 11.2 GENERAL CHARACTERISTICS (MEASURED AT 25°C) 41 TABLE 11.1 IQS213A GENERAL OPERATING CONDITIONS (A ) 41 TABLE 11.2 IQS213A CURRENT CONSUMPTION (B)..... 42 TABLE 11.3 IQS213A CURRENT CONSUMPTION (C) .... 42 TABLE 11.4 IQS213A CURRENT CONSUMPTION (D) .... 42 TABLE 11.5 START-UP AND SHUT-DOWN SLOPE CHARACTERISTICS .................................................... 43 TABLE 11.6 DEBOUNCE EMPLOYED ON IQS213A ........ 43 11.3 TIMING CHARACTERISTICS ............................ 43 1 TABLE 11.7 MAIN OSCILLATOR ................................. 43 TABLE 11.8 GENERAL TIMING CHARACTERISTICS FOR 1.80V ≤ VDDHI ≤ 3.60V ............................................. 43 TABLE 11.9 IQS213A CHARGING TIMES ..................... 43 DESCRIPTION OF USER SELECTABLE OPTIONS. 18 12 PACKAGING INFORMATION ............................44 MSOP-10 PCB FOOTPRINT DIMENSIONS: .................. 44 12.1 TAPE AND REEL SPECIFICATION .................... 45 12.2 PACKAGE MSL ............................................ 45 TABLE 12.1 MSOP-10 MSL CLASSIFICATION .............. 45 13 DEVICE MARKING ............................................46 13.1 13.2 14 ORDERING INFORMATION ..............................47 14.1 15 TOP MARKING .............................................. 46 BOTTOM MARKING ....................................... 46 GENERAL PART ORDER NUMBER .................. 47 CONTACT INFORMATION ................................48 ADDITIONAL FEATURES .................................. 24 7.1 8 9.1 9.2 9.3 10.1 MEMORY REGISTERS ................................... 31 TABLE 10.1 : IQS213A MEMORY REGISTERS.............. 31 TABLE 10.2 : IQS213A MEMORY REGISTER BITS ........ 33 10.2 MEMORY REGISTERS DESCRIPTION ............... 33 6.1 IQS213A IC TYPE ...................................... 18 6.2 SELF- / PROJECTED CAPACITANCE ................ 18 6.3 FLOAT RX ................................................... 19 6.4 OUTPUT LOGIC SELECT ................................ 19 6.5 HALT TIME .................................................. 20 6.6 LOW POWER MODES ................................... 20 TABLE 6.1 : LOW POWER MODE TIMING (TLP) .............. 21 6.7 PROXIMITY THRESHOLD ............................... 21 6.8 TOUCH THRESHOLDS ................................... 21 6.9 IQS213A SWIPE UI .................................. 22 6.10 ZERO STATES ALLOWED .............................. 22 6.11 END ON ZERO STATE ................................... 22 6.12 STATE TIMES .............................................. 22 6.13 TOUCH/SWIPE (PIN7) OUTPUT ...................... 23 6.14 AC FILTER .................................................. 23 6.15 ATI METHOD............................................... 23 6.16 BASE VALUE ............................................... 23 6.17 ATI TARGET VALUE ..................................... 23 6.18 AUTO-OFF / ADVANCED AUTO-OFF W ARNING 24 2 6.19 I C DEBUG ................................................. 24 7 COMMUNICATION ..........................................30 4.1 IQS213A - MSOP10 PIN-OUT ...................... 4 TABLE 4.1 : IQS213A PIN-OUT .................................... 4 4.2 REFERENCE DESIGN (IQS213A, SELFCAPACITANCE, ACTIVE-LOW OUTPUT) .......................... 5 5.1 CONFIGURING OF DEVICES ............................. 7 5.2 USER SELECTABLE CONFIGURATION (OTP) OPTIONS.................................................................... 8 TABLE 5.1 .................................................................. 8 TABLE 5.2 .................................................................. 9 TABLE 5.3 ................................................................ 10 TABLE 5.4 ................................................................ 11 TABLE 5.5 ................................................................ 12 TABLE 5.6 ................................................................ 13 5.3 IQS213A SETUP EXAMPLES ........................ 14 6 9 ACTIVE CHANNELS ....................................... 27 LONG TERM AVERAGE (LTA) ........................ 28 DETERMINE TOUCH OR PROX ........................ 28 ATI ............................................................ 28 RF DETECTION ............................................ 29 NOISE DETECTION ....................................... 24 ® PROXSENSE MODULE .................................... 26 8.1 8.2 8.3 8.4 8.5 CHARGE TRANSFER CONCEPTS .................... 26 ® PROXSENSE MODULE SETUP ...................... 26 SELF- OR PROJECTED CAPACITANCE ............. 26 RATE OF CHARGE CYCLES ........................... 27 TOUCH REPORT RATE.................................. 27 Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 2 of 48 October 2018 IQ Switch® 1 Functional Overview ProxSense® Series The IQS213A is a two or three channel capacitive proximity and touch sensor with variable swipe function configurations. Additional features include internal voltage regulation and reference capacitor (CS), which enables cost efficient and minimal component designs. The device offers flexible design approaches by allowing the connection of two or three sense antennas in either surface or projected capacitance configurations. For swipe function applications the device has a single logic output to indicate swipe actions and one complementary output for consecutive swipe/touch activities. The device can also be configured to operate with individual touch outputs, with an additional proximity output when implementing surface capacitance sense electrodes. Full control by a master device is achieved by configuring the logic outputs in a serial data (I2C) communication option on TO0 (SCL), TO1 (SDA) and TO2 (RDY). Note: Programming of OTP’s required to 2 enable I C operation. The device automatically tracks slow varying environmental changes via various filters, detects noise and has an Automatic Tuning Implementation (ATI) to tune the device for optimal sensitivity. 1.1 Applicability All specifications, except where specifically mentioned otherwise, provided by this datasheet are applicable to the following ranges:  Temperature: -20°C to +85°C  Supply voltage (VDDHI): 1.8V to 3.6V 2 Analogue Functionality attached to the CX pins through a charge transfer process that is periodically initiated by the digital circuitry. For projectedcapacitance configurations the capacitance is measured between the transmit (TX) and receive (CRX) pins. The measuring process is referred to as a conversion and consists of the discharging of CS and CX, the charging of CX and then a series of charge transfers from CX to CS until a trip voltage is reached. The number of charge transfers required to reach the trip voltage is referred to as the Count (CS) Value. The capacitance measurement circuitry makes use of an internal CS and voltage reference (VREG). The analogue circuitry further provides functionality for:  Power on reset (POR) detection.  Brown out detection (BOD). 3 Digital Functionality The digital processing responsible for:           functionality is Device setup from OTP settings after POR. Management of BOD and WDT events. Initiation of conversions at the selected rate. Processing of CS and execution of algorithms. Monitoring and automatic execution of the ATI algorithm. Signal processing and digital filtering. Detection of PROX and TOUCH events. Managing outputs of the device. Managing serial communications. Manage programming of OTP options. For self-capacitance configured sense electrodes the analogue circuitry measures the capacitance of the sense antennas Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 3 of 48 October 2018 IQ Switch® ProxSense® Series 4 Hardware Configuration 4.1 IQS213A - MSOP10 Pin-Out IQS213A Figure 4.1 : Pin-out of IQS213A MSOP-10 package Table 4.1 : IQS213A Pin-out 5 VREG IQS213A Pin-out Type Function Supply Input Ground Reference Analogue Sense Electrode 0 Analogue Sense Electrode 1 Supply Input Supply Voltage Input Internal Regulator Pin (Connect 1µF Analogue Output 6 SWIPE/TO2/RDY Digital Output 7 PULSE/T01/SDA Digital Output 8 AAOW/TO0/SCL Digital I/O 9 CX2 (CRX2) 10 PO/TX Analogue Digital Output Transmitter Pin 1 2 3 4 Name GND CX0 (CRX0) CX1 (CRX1) VDDHI Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved bypass capacitor) Swipe Output/Touch Output/I2C: RDY Output Pulse Output/Touch Output/I2C: SDA Output Auto-Off Warning/Touch Output/I2C: SCL Input Sense Electrode 2 / Proximity Output/ Projected Sense Electrode IQS213A Datasheet Revision 3.0 Page 4 of 48 October 2018 IQ Switch® ProxSense® Series 4.2 Reference Design (IQS213A, Self-Capacitance, Active-Low Output) Figure 4.2 : IQS213A Reference Design (Self-Capacitance, Active-Low) Note: For Active-Low configurations the external pull-up resistors (i.e. R8-R10) must be populated for correct functioning of the relevant Open-Drain (SW-OD) outputs. Resistor R11 should only be placed for a “Self-Capacitive” system when using the Active-Low (SW-OD) proximity output (pin10). R12: Place a 43Ω resistor in series with the VDDHI supply line to prevent a potential ESD induced latch-up state. Maximum supply current should be limited to 80mA on the IQS213A VDDHI pin to prevent latch-up. 4.2.2 Power Supply and PCB Layout Azoteq IC's provide a high level of on-chip hardware and software noise filtering and ESD protection (refer to application note “AZD013 – ESD Overview”). Designing PCB's with better noise immunity against EMI, FTB and ESD in mind, it is always advisable to keep the critical noise suppression components like the de-coupling capacitors and series resistors in Figure 4.2 as close as possible to the IC. Always maintain a good ground connection and ground pour underneath the IC. For more guidelines please refer to the relevant application notes as mentioned in Section 4.2.3. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 5 of 48 October 2018 IQ Switch® ProxSense® Series 4.2.3 Design Rules for Harsh EMC Environments Figure 4.3 : EMC Design Rules  Applicable application notes: AZD013, AZD015, AZD051, AZD052. 4.2.4 High Sensitivity Through patented design and advanced signal processing, the device is able to provide extremely high sensitivity to detect proximity. This enables designs to detect proximity at distances that cannot be equaled by most other products. When the device is used in environments where high levels of noise exist, a reduced proximity threshold is proposed to ensure reliable functioning of the sensor. When the capacitance between the sense antenna and ground becomes too large the sensitivity of the device may be influenced. For more guidelines on layout, please refer to application note AZD008, available on the Azoteq web page: www.azoteq.com. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 6 of 48 October 2018 IQ Switch® ProxSense® Series 5 User Configurable Options The IQS213A provides One Time Programmable (OTP) user options, which can be programmed to change the device’s default start-up configuration. Blank/Un-programmed devices has a default OTP configuration = 00000000 (See Section 5.2 for OTP options). With the use of Azoteq’s IQS213A GUI software, the IQS213A can enter streaming mode in a start-up state (Test Mode) where the OTP options can be configured and evaluated, before selecting OTP’s for programming. NOTE: I2C-communication is NOT ENABLED by Default, and the device will be in a Stand-Alone mode configuration with GPIO outputs. To enable I2C-communication, the I2C-debug option in OTP bank 4 has to be programmed. The configuration of the device can be done on packaged devices or in-circuit. In-circuit configuration may be limited by the type and/or values of external components chosen. Please see Section 5.3 for IQS213A device setup and output configuration examples. 5.1 Configuring of Devices Azoteq offers a Configuration Tool (CT210 or later) and associated software (USBProg.exe) that can be used to program the OTP user options for prototyping purposes. More details regarding the configuration of the device with the USBProg program can be found in "AZD007 - USBProg Overview" available on the Azoteq website. For further enquiries regarding this subject, please contact your local distributor or submit enquiries to Azoteq at: ProxSenseSupport@azoteq.com Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 7 of 48 October 2018 IQ Switch® ProxSense® Series 5.2 User Selectable Configuration (OTP) Options Table 5.1 : User Selectable Configuration (OTP) Options : Bank 0 bit7 THALT1 Bank 0 THALT0 Bank0: bit7:6 LOGIC FLOAT RX bit0 PROJ IC TYPE2 IC TYPE1 THALT1:THALT0: LTA Halt Time IC TYPE0 Section 6.5 00 = 2.5s 01 = 20s 10 = 60s 11 = Never Bank0: bit5 LOGIC: Output Logic Section 6.4 1 0 = Active Low 1 = Active High Bank0: bit4 FLOAT RX: Float Sense Electrodes Section 6.8 0 = No 1 = Yes Bank0: bit3 PROJ: Capacitive Technology Section 6.2 0 = Self Capacitance 1 = Projected Capacitance Bank0: bit2:0 1 IC TYPE: Select IC type Section 6.1 000 = 1zz 12z z2z - 2CH SWIPE 001 = 1zz x2x zz3 - 3CH SWIPE (Thresholds * 2) 010 = 1zz z2z zz3 - 3CH SWIPE 011 = 1zz 12z z2z z23 zz3 - 3CH SWIPE 100 = 2CH Normal - 2 Channel Touch Sensor 101 = 3CH Normal - 3 Channel Touch Sensor 110 = 1zz 1xz x2x zx3 zz3 - 3CH SWIPE 111 = 1zz, x2x, zz3 - 3CH SWIPE Active Low configurations are software open-drain (SW OD). Note: The proximity output on the PO/TX-pin (pin 10) is multiplexed with the transmit signal (TX) for projected capacitance electrodes, and is Active High ONLY for Projected configurations. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 8 of 48 October 2018 IQ Switch® ProxSense® Series Table 5.2 : User Selectable Configuration (OTP) Options : Bank 1 bit7 CH2 TTH1 Bank 1 CH2 TTH0 Bank1: bit7:6 CH1, CH3 TTH1 PTH DIV LP1 LP0 Section 6.8 TTH ALT = 1 00 = 4 00 = 22 01 = 8 01 = 28 10 = 12 10 = 36 11 = 16 11 = 48 CH1, CH3 TTH: Ch 1 & Ch 3 Touch Threshold TTH ALT = 0 Bank1: bit3 TTH ALT CH2 TTH1:CH2 TTH0: Channel 2 Touch Threshold TTH ALT = 0 Bank1: bit5:bit4 CH1, CH3 TTH0 bit0 Section 6.8 TTH ALT = 1 00 = 4 00 = 22 01 = 8 01 = 28 10 = 12 10 = 36 11 = 16 11 = 48 TTH ALT: Alternative Touch Thresholds Section 6.8 0 = No 1 = Yes Bank1: bit2 PTH: Proximity Threshold Selection Section 6.7 0 = 3 Counts 1 = 8 Counts Bank1: bit1:0 Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved LP1:LP0: Low Power Selection 00 = NP - Normal Power 01 = 128ms - Low Power Mode 1 10 = 256ms - Low Power Mode 2 11 = 512ms - Low Power Mode 3 IQS213A Datasheet Revision 3.0 Section 6.6 Page 9 of 48 October 2018 IQ Switch® ProxSense® Series Table 5.3 : User Selectable Configuration (OTP) Options : Bank 2 bit7 ACF Bank 2: SWIPE IC Pin7_OUT Bank2: bit7 CHG_FRQ Min_State Zero_End bit0 Zero_State SWIPE UI1 ACF: AC Filter Selection SWIPE UI0 Section 6.14 0 = Disabled 1 = Enabled Bank2: bit6 Pin7_OUT: SWIPE IC Pin 7 Output Selection Section 6.13 0 = Touch 1 = Pulse Bank2: bit5 Bank2: bit4 CHG_FRQ: Charge Transfer Frequency 0 = 0.5MHz / 1.0MHz (Self - / Projected Capacitance) 1 = 1.0MHz / 2.0 MHz (Self - / Projected Capacitance) Min_State: Minimum State Time Section 8.3 Section 6.12 0 = 1 Sample 1 = 2 Samples Bank2: bit3 Zero_End: End Swipe on Zero State (zzz) Section 6.11 0 = Disabled 1 = Enabled Bank2: bit 2 Zero_State: Allow Zero States In Swipe Sequence Section 6.10 0 = Disabled 1 = Enabled Bank2: bit 1:bit0 SWIPE UI1: SWIPE UI0: Swipe UI Selection Section 6.9 00 = Single Direction 01 = Bi-Directional 10 = Directional 11 = Dual Swipe Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 10 of 48 October 2018 IQ Switch® ProxSense® Series Table 5.4 : User Selectable Configuration (OTP) Options : Bank 2 bit7 ACF Bank2: bit7 Bank 2: Normal Touch IC CHG_FRQ bit0 Toggle CH3 ACF: AC Filter Selection Toggle CH2 Toggle CH1 Section 6.14 0 = Disabled 1 = Enabled Bank2: bit6 Bank2: bit5 CHG_FRQ: Charge Transfer Frequency Section 8.3 0 = 0.5MHz / 1.0MHz (Self - / Projected Capacitance) 1 = 1.0MHz / 2.0 MHz (Self - / Projected Capacitance) Bank2: bit4 Bank2: bit3 Bank2: bit 2 Toggle CH3: Channel 3 Touch Output = Toggle 0 = Disabled 1 = Enabled Bank2: bit 1 Toggle CH2: Channel 2 Touch Output = Toggle 0 = Disabled 1 = Enabled Bank2: bit 0 Toggle CH1: Channel 1 Touch Output = Toggle 0 = Disabled 1 = Enabled Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 11 of 48 October 2018 IQ Switch® ProxSense® Series Table 5.5 : User Selectable Configuration (OTP) Options : Bank 3 bit7 Bank 3 AAO_CLR Bank3: bit7 System Use Bank3: bit6 System Use Bank3: bit5 System Use Bank3: bit4 System Use Bank3: bit3 AAO_CLR: Clear Auto-Off Timer On Event bit0 AAO ATI_Target ATI_Base Section 6.18 0 = Touch Event 1 = Proximity Event Bank3: bit 2 AAO: Advanced Auto-Off Function Selection Section 6.18 0 = Enabled 1 = Disabled Bank3: bit 1 Bank3: bit 0 ATI_Target: ATI Target Value Proximity Touch 0= 320 160 1= 640 320 ATI_Base: ATI Base Value (All Channels) Section 6.17 Section 6.16 0 = 75 1 = 100 Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 12 of 48 October 2018 IQ Switch® ProxSense® Series Table 5.6 : User Selectable Configuration (OTP) Options : Bank 4 bit7 Bank 4 bit0 2 I C Debug Bank4: bit7 System Use Bank4: bit6 System Use Bank4: bit5 System Use Bank4: bit4 System Use Bank4: bit3 I C Debug: I C Interface (Default = Event-Mode) 2 2 Section 6.19 0 = Disabled 1 = Enabled Bank4: bit 2 System Use Bank4: bit 1 System Use Bank4: bit 0 System Use Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 13 of 48 October 2018 IQ Switch® ProxSense® Series 5.3 IQS213A Setup Examples 5.3.1 Example 1: 3-Channel Self Capacitive, Active Low Logic Output, SwipeSwitch with Auxiliary Touch Output. Example 1 (see Figure 5.1) illustrates the user interface (UI) and device outputs for a 3-Channel Self Capacitive SwipeSwitch (output on pin 6), in an active low configuration with the Directional UI and Auxiliary Touch Output on pin 7. 5.3.1.1 Selected User Configuration Options (Example 1): bit7 THALT1 0 THALT0 0 LOGIC 0 Bank 0 FLOAT RX N/A PROJ 0 IC TYPE2 * IC TYPE1 * bit0 IC TYPE0 * *** The IC TYPE can be any 3-Channel SwipeSwitch™ option, e.g. 001,110 or 111. THALT1:0 = 00 – 2.5s Halt time selected for this example. bit7 CH2 TTH1 CH2 TTH0 N/A N/A bit7 ACF N/A Pin7_OUT 0 bit7 CH1, CH3 TTH1 N/A CHG_FRQ N/A Bank 1 CH1, CH3 TTH0 N/A bit0 TTH ALT PTH DIV LP1 LP0 N/A N/A N/A N/A Bank 2: SWIPE IC Min_State N/A Zero_End N/A Zero_State N/A Bank 4 2 I C Debug 0 SWIPE UI1 1 bit0 SWIPE UI0 0 bit0 5.3.1.2 Device outputs (Directional SwipeSwitch™ UI) Figure 5.1 : IQS213A setup example 1 Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 14 of 48 October 2018 IQ Switch® ProxSense® Series 5.3.2 Example 2: 3-Channel Projected Capacitive, Active High Logic Output, SwipeSwitch with Auxiliary Swipe Pulse Output. Example 2 (see Figure 5.2) illustrates the user interface (UI) and device outputs for a 3-Channel Projected Capacitive SwipeSwitch (output on pin 6), in an active high configuration with the BiDirectional UI and Auxiliary Swipe Pulse Output on pin 7. 5.3.2.1 Selected User Configuration Options (Example 2): bit7 THALT1 N/A THALT0 N/A Bank 0 LOGIC 1 FLOAT RX N/A CH1, CH3 TTH0 N/A Min_State N/A PROJ 1 IC TYPE2 * IC TYPE1 * bit0 *** The IC TYPE can be any 3-Channel SwipeSwitch option, e.g. 001,110 or 111. bit7 CH2 TTH1 CH2 TTH0 N/A N/A CH1, CH3 TTH1 N/A Pin7_OUT 1 CHG_FRQ N/A bit7 ACF N/A Bank 1 IC TYPE0 * bit0 TTH ALT PTH DIV LP1 LP0 N/A N/A N/A N/A Zero_State N/A SWIPE UI1 0 SWIPE UI0 1 Bank 2: SWIPE IC Zero_End N/A bit0 Pin7_OUT = 1 : The output on pin 7 will be a pulse signal *(within a 2-second window), of which the pulse length depends on the direction of the swipe event. See Section 6.13. *The 2-second window is reset after each swipe event. bit7 Bank 4 2 I C Debug 0 bit0 5.3.2.2 Device outputs (Bi-Directional SwipeSwitch UI) Figure 5.2 : IQS213A Setup example 2 Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 15 of 48 October 2018 IQ Switch® ProxSense® Series 5.3.3 Example 3: Normal Mode Operation Example 3 illustrates the user interface (UI) and device outputs for a 2- or 3-Channel Normal Mode (TOUCH) Device, with optional toggle state outputs. Note that the lower three bits of Bank2 are reserved for Toggle options, when the IC TYPE is selected in a Normal Mode configuration. The Normal Mode (i.e Touch) device can be either Self- or Projected Capacitive with either Active High or Active Low (Logic) outputs. 5.3.3.1 Example 3.1: 2-Channel Normal Mode – No Toggle Active, Active Low Logic bit7 THALT1 N/A THALT0 N/A LOGIC 0 bit7 Bank 0 FLOAT RX N/A PROJ N/A Bank 2: Normal Touch IC ACF CHG_FRQ N/A N/A bit0 IC TYPE2 1 IC TYPE1 0 IC TYPE0 0 Toggle CH3 0 Toggle CH2 0 Toggle CH1 0 bit0 Figure 5.3 : IQS213A Setup example 3.1 Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 16 of 48 October 2018 IQ Switch® ProxSense® Series 5.3.3.2 Example 3.2: 3-Channel Normal Mode – All Toggles Active, Active High Logic bit7 THALT1 N/A THALT0 N/A LOGIC 1 bit7 Bank 0 FLOAT RX N/A PROJ N/A Bank 2: Normal Touch IC ACF CHG_FRQ N/A N/A bit0 IC TYPE2 1 IC TYPE1 0 IC TYPE0 1 Toggle CH3 1 Toggle CH2 1 Toggle CH1 1 bit0 Figure 5.4 : IQS213A Setup example 3.2 Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 17 of 48 October 2018 IQ Switch® ProxSense® Series 6 Description of Selectable Options User This section briefly describes the individual user programmable options of the IQS213A, with additional information and detailed descriptions being provided in Section 8. Thresholds and other settings can also be evaluated in Test Mode streaming without programming the OTP options. For the appropriate software, please visit: www.azoteq.com 6.1 IQS213A IC Type The IQS213A has six selectable SwipeSwitch™ setup configurations, allowing the user maximum freedom in the design of the intended application. The device type configuration specifies the required user input, which is identified by a sequence of a combination of input states, where a [number] (e.g. 1, 2 or 3) indicates a touch condition/state on that specific channel, a [zcharacter] indicates a zero condition/state and a [x-character] indicates a “don't care” condition/state (i.e. a number or zero condition is acceptable). The input states related to sequences accepting x-character conditions are also referred to as relaxed states.  2CH SWIPE - 1zz 12z z2z 2-Channel swipe switch operation. :  3CH SWIPE – 1zz x2x zz3 (TH*2) 3-Channel swipe switch operation. :  3CH SWIPE - 1zz z2z zz3 3-Channel swipe switch operation. :  3CH SWIPE - 1zz 12z z2z z23 zz3 : 3-Channel swipe switch operation.  3CH SWIPE - 1zz 1xz x2x zx3 zz3 : 3-Channel swipe with relaxed states.  3CH SWIPE - 1zz x2x zz3 : 3-Channel swipe with relaxed states. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved The IQS213A also has 2 selectable normal setup configurations, which allows the user to implement standard touch and proximity sensing features.  2CH Normal Mode : 2-Channel Normal Touch operation.  3CH Normal Mode : 3-Channel Normal Touch operation. With the device setup in either 2-channel or 3-channel Normal Mode, touch events corresponding to the different sense electrodes will be output on TO0 (pin 8), TO1 (pin 7) and TO2 (pin 6), with a proximity output available on PO (pin 10). During Normal Mode operation, setting the different “Toggle_CHx” bits in Bank 2, will enable the touch output signals to toggle. 6.2 Self- / Projected Capacitance Enabling the projected capacitance option, will cause the measurement of the sense electrode capacitance between the transmit (TX) and receive (CRX) pins. The proximity output on the PO/TX-pin (pin 10) is multiplexed with the transmit signal (TX) for projected capacitance electrodes, and is Active High ONLY for such configurations. The implementation of a projected capacitance sense electrode will result in a higher charge frequency (i.e. f Cm = 1MHz) compared to that of a self capacitance configuration (i.e. fCs= 500kHz). Setting bit5 in Bank2 will double the charge frequency for both projected- and self capacitance configurations (i.e. fCm / fCs= 2MHz / 1MHz). A higher charge frequency selection is preferred for increased immunity against aqueous substances when used in most projected capacitance configurations. IQS213A Datasheet Revision 3.0 Page 18 of 48 October 2018 IQ Switch® ProxSense® Series 6.2.1 Capacitive Sense Electrode Design Samples 6.2.1.1 Self Capacitance Electrodes 2-Channel Self Capacitance Electrode 3-Channel Self Capacitance Electrode Figure 6.1 : Self Capacitance Swipe Switch Sample Electrodes. 6.2.1.2 Projected Capacitance Electrodes 2-Channel Projected Capacitance Electrode 3-Channel Projected Capacitance Electrode Figure 6.2 : Projected Capacitance Swipe Switch Sample Electrodes. 6.3 Float Rx 6.4 Output Logic Select During the charge transfer process (see Figure 8.1) the channels that are not being processed during the current cycle, is effectively grounded to decrease the effects of noise-coupling between the sense electrodes. Selecting the "Float RX" option (Bank0 bit4), will thus result in the noncurrent channels to float (i.e. not grounded) during the charge cycle of the current channel. The IQS213A can be set to sink or source current in stand-alone mode (I2C Debug = Disabled), by setting the logic output Active High (Push-Pull) or Active Low (SW OD). Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved For Active Low operation, the device output pins are set in a software open-drain (SW OD) configuration, which requires the use of external pull-up resistors on the output pins. The proximity output on the PO/TX-pin (pin 10) is multiplexed with the transmit signal (TX) for projected capacitance electrodes, and is Active High ONLY for Projected configurations. Thus for self capacitance IQS213A Datasheet Revision 3.0 Page 19 of 48 October 2018 IQ Switch® ProxSense® Series configurations, the proximity output on PO (pin10) depends on the selected output logic (Bank0 bit5). 6.5 Halt Time The Halt Timer is started when a proximity or touch event occurs and is restarted when that event is removed or reoccurs. When a proximity condition occurs on any of the channels, the LTA (Long-Term Average) value for that channel will be "halted", thus its value will be kept fixed, until the proximity event is cleared, or the halt timer reaches the halt time. The halt timer will count to the selected halt time (tHALT), which can be configured in the user selectable options (i.e. Bank0 bit7:6), and if the timer expires, all outputs will be cleared. It is possible that the CS (Count) value could be outside the ATI band (ATI Target +12.5%) when the timer expires, which will cause the device to perform a re-ATI event. The designer needs to select a halt timer value (tHALT) to best accommodate the required application:  2.5 seconds : Halt LTA for 2.5 seconds after the last proximity or touch event.  20 seconds : Halt LTA for 20 seconds after the last proximity or touch event.  60 seconds : Halt LTA for 60 seconds after the last proximity or touch event.  Never : Never halt LTA  With the 'Never' option, the detection of a proximity or touch event will not halt the LTA and the LTA will adjust towards the CS value until the CS value is reached. The touch and proximity output of a channel will thus be cleared automatically when the difference between the LTA and CS is less than the specified threshold value. 6.6 Low Power Modes The IQS213A IC has three low power modes specifically designed to reduce current consumption for battery applications. The power modes are implemented around the occurrence of a charge cycle every tSAMPLE seconds (refer to Table 6.1). Lower sampling frequencies typically yield significant lower power consumption (but also decreases the response time). During normal operation charge cycles are initiated approximately every 2.6ms in the stand-alone setup and 3.9ms in the I2C debug setup. This is referred to as Normal Power Mode (NP). The IQS213A by default charges in Normal Power Mode. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved While in any low power mode, only Channel 0 is active and the device will zoom to NP whenever the CS value indicates a possible proximity or touch event on CH0 (refer to Figure 6.3). This improves the response time. The device will remain in NP for tZOOM seconds and then return to the selected low power mode. The Zoom function allows reliable detection of events with the current samples being produced at the NP rate. Please see Section 8.4 or refer to “Application Note AZD079 – IQS213 Touch response rate” for more information. IQS213A Datasheet Revision 3.0 Page 20 of 48 October 2018 IQ Switch® ProxSense® Series Table 6.1 : Low Power Mode Timing (tLP) Power Mode tSAMPLE tSAMPLE (Stand-alone) (I2C ) NP (Default) 2.6 ms 3.9ms LP1 128 ms 128ms LP2 256 ms 256ms LP3 512 ms 512ms Figure 6.3 : LP Modes – Charge Cycles 6.7 Proximity Threshold The IQS213A has 2 proximity threshold (PTH) settings. The proximity threshold is selected by the designer to obtain the desired sensitivity and noise immunity. The proximity event is triggered based on the selected proximity threshold, which is either 3 or 8 counts. The proximity threshold is expressed in terms of counts, the same as the CS value. For proximity events, the difference between the LTA and CS (in counts) of the proximity channel should be greater than PTH for at least 4 consecutive samples, unless the CS delta is greater than the touch threshold of any active channel. (See Section 8.8) 6.8 Touch Thresholds The IQS213A has 8 touch threshold settings. The touch threshold is selected by the designer to obtain the desired touch sensitivity. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved The touch event is triggered based on the selected touch threshold, which is expressed as a fraction of the LTA, given by: ܶܶ‫ ܪ‬ൌ ‫ ݔ‬Τʹͷͷ ൈ ‫ܣܶܮ‬. (See Section 8.8) For a touch event, the difference between LTA and CS (counts) of the touch channel should be greater than the selected touch threshold for at least 2 consecutive samples. On the IQS213A device, the touch threshold settings are grouped for channels 1 and 3 (CH1,3 TTH) and is separate for channel 2 (CH2 TTH). The IQS213A device is by default setup without the alternative threshold settings. The alternative threshold values can be selected by setting the TTH_ALT bit (i.e. bit3 in Bank1). If for specific applications the designer requires larger touch threshold values than the available selections, they may select the “3CH SWIPE – 1zz x2x zz3 (TH*2)” IC TYPE in Bank0 of the user configurable options. IQS213A Datasheet Revision 3.0 Page 21 of 48 October 2018 IQ Switch® ProxSense® Series This selection is for a three channel sense electrode configuration only and will automatically multiply the threshold selections by two. 6.9 IQS213A SWIPE UI The IQS213A has 4 selectable swipe switch user interface (UI) configurations. The swipe UI specifies the required event(s) to activate the outputs of the device:  Single Direction: The device only acknowledges swipe events in the direction of CH1>CH2 for a 2-channel and CH1>CH2>CH3 for a 3-channel device setup.  Bi-Directional: The device acknowledges swipe events in both the forward (CH1>CH2>...) and reverse (...>CH2>CH1) directions.  This grants the designer a certain degree of freedom in the selected device sensitivity and implemented sense electrode. If for example the IC type is selected to be “3CH SWIPE - 1zz z2z zz3”, then the sequence ‘1zz zzz z2z zzz zz3’ of state combinations will also be acknowledged as a valid swipe event. 6.11 End on Zero State Setting the Zero_End bit in Bank2, will append an additional zero or "no touch" state to the required sequence of state combinations. If for example the IC type is selected to be “3CH SWIPE - 1zz z2z zz3”, then the sequence ‘1zz z2z zz3 zzz’ of state combinations will be acknowledged as a valid swipe event ONLY. Directional: A swipe event in the forward (CH1>CH2>...) direction will enable the swipe output (ON) and a swipe in the reverse (...>CH2>CH1) direction will disable the output (OFF).  each sequence of the selected IC type (refer to Section 6.1 for IC types). Dual Swipe: This UI requires a swipe event in one direction, followed by a swipe event in the opposite direction within 1 second, to enable the swipe output (ON). Thereafter, a single swipe in any direction will subsequently disable the swipe output again (OFF). 6.10 Zero States Allowed Setting the Zero_State bit in Bank2, will allow the occurrence of zero or "no touch" conditions between the different state combinations in Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved 6.12 State Times The minimum, maximum and overall swipe state times controls the effective period during which a successful swipe event can be recognized. The state times are defined in swipe state samples, where each sample period tSTATE is equal to 4 charge transfer periods. For stand-alone device operation this results in a state sample time of approximately tSTATE = 10.4ms. The state time values can also be set up or changed in I2C debug mode. 6.12.1 Minimum State Time The minimum state time (tMIN) defines the minimum period (in multiples of tSTATE) for which each combination of states (e.g. 1zz) must be present during processing of the current sequence of the state combination. Selecting shorter minimum state times will effectively allow faster swipe events. IQS213A Datasheet Revision 3.0 Page 22 of 48 October 2018 IQ Switch® ProxSense® Series 6.12.2 Maximum State Time The maximum state time defines the maximum period for which each combination of states (e.g. 1zz) may be present during processing of the current sequence of the state combination. This value is fixed at tMAX = 45*tSTATE by default, but is accessible in I2C debug mode. Selecting longer maximum state times will effectively allow slower swipe events. 6.12.3 Overall State Time The overall state time is the total allowable time for performing a swipe event and is by default set to 1 second. This value can also be changed in I2C debug mode in steps of 250ms. 6.13 Touch/Swipe (Pin7) Output The IQS213A has one complementary output on pin 7 of the IC. This pin can be configured to output either touch events or pulses upon swipe events, after the swipe output (pin 6) has been enabled. By default the IQS213A will output a logic signal for touch events on any of the three sense electrodes. If the Pin7_Out bit in Bank2 is set, the device will output a short pulse for every consecutive swipe event within 2 seconds after the first swipe event. The generated pulses have different pulse widths (tPULSE), depending on the direction of the swipe event:  Long Pulse: A long pulse (tPULSE ≈ 9ms) will be output for swipes in the forward (CH1>CH2...) direction.  Short Pulse: A short pulse (tPULSE ≈ 3ms) will be output for swipes in the reverse (...>CH2>CH1) direction. 6.14 AC Filter The AC filter can be implemented to provide better stability of the proximity channel’s count (CS) measurements in electrically noisy environments by setting the ACF bit in Bank2. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved The AC filter also enforces a longer minimum sample time for detecting proximity events, which may result in a slower response rate when the device enters low power modes. 6.15 ATI Method In the stand-alone configuration the IQS213A is automatically set up in Full ATI to set up the device for optimal sensitivity. In the I2C debug configuration, the IQS213A can be set up to start in two ways, Full ATI and Partial ATI. In Full ATI mode, the device automatically selects the multipliers through the ATI algorithm to setup the IQS213A as close as possible to its default sensitivity for the environment where it was placed. The designer can, however, select Partial ATI, and set the multipliers to a pre configured value. This will cause the IQS213A to only calculate the compensation (not the compensation and multipliers as in Full ATI), which allows the freedom to make the IQS213A more or less sensitive for its intended environment of use. (Please refer to Section 8.9.) 6.16 Base Value The IQS213A has the option to change the base value of all channels during the ATI algorithm. Depending on the application, this provides the user with another option to select the sensitivity of the IQS213A without changes in the hardware (CX sizes and routing, etc). By setting the ATI_Base bit in Bank3, the base value can be set to be 75 or 100. A lower base value will typically result in a higher sensitivity of the device. (Refer to Section 8.9) 6.17 ATI Target Value The default target counts of the IQS213A are 320 for the proximity channel, and 160 for the touch channels. However, for some applications, a more sensitive device and higher target is required. IQS213A Datasheet Revision 3.0 Page 23 of 48 October 2018 IQ Switch® ProxSense® Series Therefore, the ATI_Target bit in Bank3 can be set, changing the targets to 640 for the proximity channel, and 320 for the touch channels. (See Section 8.9) 6.18 Auto-Off / Advanced AutoOff Warning To prevent battery drainage in the unlikely event of a false activation of the output load, the IQS213A is equipped with an Auto-Off functionality. The Auto-Off (AAO) feature can be disabled by setting the AAO bit in Bank3. 6.18.1 Advanced (AAOW) Auto-Off Warning In stand-alone operation the Advanced AutoOff Warning (AAOW) timer is set for 10 minutes. After the first warning, a second warning will be given after 30s. Another 30s after the second warning, the device will switch off automatically (i.e. disable all outputs). In I2C operation the Auto-Off (AAO) and Advanced Auto-Off Warning (AAOW) timers can be set to any value in multiples of 30s. 6.18.2 AAOW Clear / Reset The AAO timer is by default cleared (reset) on a touch event on any channel. Setting the AAO_CLR bit in Bank3, the AAO timer will be reset upon a proximity event. be active low when it is ready for communication, and it will go high when it is doing conversions. The IQS213A will not acknowledge (ACK) on its address while the RDY line is high (i.e. while the IQS213A is doing conversions). 7 Additional Features 7.1 Noise Detection The IQS213A has advanced integrated immunity to RF noise sources such as GSM cellular telephones, DECT, Bluetooth and WIFI devices. Design guidelines should however be followed to ensure the best noise immunity. (Please see Section 8.10) 7.1.1 Notes for layout:  A ground plane should be placed under the IC, except under the CX lines.  Place the sensor IC as close as possible to the sense electrodes.  All the tracks on the PCB must be kept as short as possible.  The capacitor between VDDHI and GND as well as between VREG and GND must be placed as close as possible to the IC.  A 100pF capacitor can be placed in parallel with the 1uF capacitor between VDDHI and GND. Another 100pF capacitor can be placed in parallel with the 1uF capacitor between VREG and GND.  When the device is too sensitive for a specific application a parasitic capacitor (max 5pF) can be added between the CX line and ground.  Proper sense antenna and button design principles must be followed.  Unintentional coupling of sense antenna to ground and other circuitry must be limited by increasing the distance to these sources. 6.19 I2C Debug A streaming option is available that allows for serial data communication on the IQS213A. Data streaming is done via an I2C compatible 3-wire interface, which consist of a data (SDA), clock (SCL) and ready (RDY) line (for IQS213A pin-out refer to Figure 4.1). The IQS213A can only function as a slave device on the bus, and will only acknowledge on address 0x44H. The RDY line is to be used by the host controller as an indication of when to start communication to the device. The RDY line will Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 24 of 48 October 2018 IQ Switch® ProxSense® Series  In some instances a ground plane some distance from the device and sense antenna may provide significant shielding from undesirable interference.  However, if after proper layout, interference from an RF noise source persists, see application note AZD015. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 25 of 48 October 2018 IQ Switch® ProxSense® Series 8 ProxSense® Module The IQS213A contains a ProxSense® module that uses patented technology to provide detection of PROX/TOUCH on numerous sensing lines. The ProxSense® module is a combination of hardware and software, based on the principles of charge transfer measurements. For I2C communication related data registers, please refer to the IQS213A Memory Map in Section 10. 8.1 Charge Transfer Concepts Capacitance measurements are taken with a charge transfer process that is periodically initiated. Self capacitance sensing measures the capacitance between the sense electrode (Cx) relative to ground. integer values). The CS values (12 bit unsigned integer values) are processed and compared to the LTA to detect Touch and Proximity events. For more information regarding capacitive sensing, refer to the application note: “AZD004 – Azoteq Capacitive Sensing”. Please note: Attaching scope probes to the Cx/CTX/CRX pins will influence the capacitance of the sense electrodes and therefore the related CS values of those channels. This will have an instant effect on the CS measurements. 8.2 ProxSense® Module Setup The IQS213A samples its channels in 4 time slots, with one internal Cs capacitor. The charge sequence is illustrated in Fig. 8.1. Projected capacitance sensing measures the capacitance between 2 electrodes referred to as the transmitter (CTX) and receiver (CRX). The measuring process is referred to as a charge transfer cycle and consists of the following:  Discharging of an internal sampling capacitor (Cs) and the antenna capacitors (self: Cx or projected: CTX & CRx) on a channel.  charging of Cx’s / CTX’s connected to the channel  and then a series of charge transfers from the Cx’s / CRX’s to the internal sampling capacitors (Cs), until the trip voltage is reached. The number of charge transfers required to reach the trip voltage on a channel is referred to as the Count or CS value. The device continuously repeats charge transfers on the sense electrodes connected to the Cx pin. For each channel a Long Term Average (LTA) is calculated (12 bit unsigned Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved Figure 8.1 IQS213(A) Charge Transfers The IQS213A charges its four channels, CH0 (Distributed Proximity Channel) and three Touch Channels (CH1, CH2 and CH3) independently during the four time slots. During these time slots, the non-current channels can either be grounded or set to float. 8.3 Self- or Projected Capacitance The IQS213A IC can be used in either self- or projected capacitance configurations. The IC is default in a 2-channel self capacitance setup. This can be changed to a projected capacitance configuration in the user selectable options (Bank0 bit3). The IQS213A Datasheet Revision 3.0 Page 26 of 48 October 2018 IQ Switch® ProxSense® Series technology enabled on the IC will be reported in the SYSFLAGS register. The IQS213A has two selectable charge transfer frequencies. For projected capacitance sense electrodes the charge frequency is by default set at fCm = 1MHz, and for self capacitance configurations fCs= 500kHz. Setting the CHG_FRQ bit in Bank2 will double the charge frequency for both projected- and self capacitance configurations (i.e. fCm / fCs= 2MHz / 1MHz). A higher charge frequency selection is preferred for increased immunity against aqueous substances when used in most projected capacitance electrode configurations. 8.4 Rate of Charge Cycles 8.4.1 Normal Power rate With the IQS213A in Normal Power (NP) mode, the sense channels are charged at a fixed sampling frequency (fSAMPLE) per channel. This is done to ensure regular samples for processing of results. It is calculated as each sample having a time (tSAMPLE = charge period (tCHARGE) + computation time)) of approximately 2.6ms, thus the time between consecutive samples on a channel (tCHANNEL) will optimally be tSAMPLE = 4 * tSAMPLE ≈ 10.4ms (or 96Hz). The charge sequence and timings are illustrated in Figure 8.2. If a channel is thus disabled, the sampling rate on the remaining channels will reduce with approximately 2.6ms. 8.4.2 Low Power rates Low current consumption charging modes are available. In any Low Power (LP) mode, there will be an applicable low power time (tLP). This is determined by the LP_PERIOD register. The value written into this register multiplied by 16ms will yield the LP time (tLP). Please note that this time is only applicable from value 03h and higher loaded into the LP_PERIOD register. The values 01h and 02h will have a different time. See Table 6.1 for all timings. With the detection of an undebounced proximity event the IC will zoom to NP mode, allowing a very fast reaction time for further possible touch / proximity events. All active channels will be consecutively charged every TLP. If a LP rate is selected through register LP_Period and charging is not in the zoomed in state (NP mode), the LP_Active bit (SYSFLAGS register) will be set. 8.5 Touch Report Rate During Normal Mode operation, the touch report rate of the IQS213A device depends on the charge transfer frequency, the number of channels enabled and the length of communications performed by the master device. 8.6 Active channels The user has the option to enable the third channel (CH3) during I2C operation. This can be done in the SWIPE_SETTINGS register (SET_3CH bit). Only two channels (CH1 and CH2) are default enabled. Note: During Low Power (LP) modes only CH0 is active. Figure 8.2 Signals on CX’s / CRX’s during Normal Power Mode. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 27 of 48 October 2018 IQ Switch® ProxSense® Series 8.7 Long Term Average (LTA) The LTA filter can be seen as the baseline or reference value. The LTA is calculated to continuously adapt to any environmental drift. The LTA filter is calculated from the CS value for each channel. The LTA filter allows the device to adapt to environmental (slow moving) changes/drift. Actuation (Touch or Prox) decisions are made by comparing the CS value with the LTA reference value. The 12bit LTA value is contained in the LTA_H and LTA_L registers. Please refer to Section 6.5 for LTA Halt Times. adjust the sample value for an attached sensing antenna. ATI allows the designer to optimize a specific design by adjusting the sensitivity and stability of each channel through the adjustment of the ATI parameters. The IQS213A has an automated ATI function. The auto-ATI function is default enabled, but can be disabled by setting the ATI_OFF and ATI_Partial bits in the PROX_SETTINGS registers. The ATI_Busy bit in the SYSFLAGS register will be set while an ATI event is busy. 8.9.1 ATI Sensitivity 8.8 Determine Touch or Prox An event is determined by comparing the CS with the LTA. Since the CS reacts differently when comparing the self- with the projected capacitance technology, the user should consider only the conditions for the technology used. An event is recorded if:  Self: CS < LTA – Threshold  Projected: CS > LTA + Threshold Threshold can be either a Proximity or Touch threshold, depending on the current channel being processed. Please refer to Section 6.7 and 6.8 for proximity and touch threshold selections. 8.9 ATI The Automatic Tuning Implementation (ATI) is a sophisticated technology implemented on the new ProxSense® series devices. It allows for optimal performance of the devices for a wide range of sense electrode capacitances, without modification or addition of external components. The ATI allows the tuning of two parameters, an ATI Multiplier and an ATI Compensation, to Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved In I2C mode, the designer can specify the global BASE value for all channels and the TARGET values for the proximity (CH0) and touch (CH1,CH2,CH3) channels. A rough estimation of sensitivity can be calculated as: ܵ݁݊‫ ݕݐ݅ݒ݅ݐ݅ݏ‬ൌ  ܶ‫ܶܧܩܴܣ‬ ‫ܧܵܣܤ‬ As can be seen from this equation, the sensitivity can be increased by either increasing the Target value or decreasing the Base value. It should, however, be noted that a higher sensitivity will yield a higher noise susceptibility. 8.9.2 ATI Target The target is reached by adjusting the COMPENSATION bits for each channel. The target value is written into the respective channel’s TARGET registers. The value written into these registers multiplied by 8 will yield the new target value. 8.9.3 ATI Base (MULTIPLIER) The following parameters will influence the base value:  CS_SIZEi: Size of sampling capacitor. i Changing CS_SIZE if ATI_OFF = 0 will change CS IQS213A Datasheet Revision 3.0 Page 28 of 48 October 2018 IQ Switch® ProxSense® Series  PROJ_BIAS bits: Adjusts the biasing of some analogue parameters in the projected capacitive operated IC. (Only applicable in projected capacitance mode.)  MULTIPLIER bits. The base value used for the ATI function can be implemented in 2 ways: 1. ATI_PARTIAL = 0. ATI automatically adjusts MULTIPLIER bits to reach a selected base valueii. Base values are available in the BASE_VALUE register. Noise affected samples are not allowed to influence the LTA filter, and also do not contribute to proximity or touch detection. With the detection of noise, the NOISE_FOUND bit in SYSFLAGS will be set. 8.10.1 RF detector sensitivity The sensitivity of the RF detector can be selected by setting an appropriate RF detection voltage through the RF_TRIM bits. Please see application note AZD015 for further details regarding this option. 2. ATI_PARTIAL = 1. The designer can specify the multiplier settings. These settings will give a custom base value from where the compensation bits will be automatically implemented to reach the required target value. 8.9.4 Re-ATI An automatic re-ATI event will occur if the CS is outside its re-ATI limits. The re-ATI limit is calculated as the target value divided by 8. For example: Target = 320 Re-ATI will occur if CS is outside 320±40. During I2C operation, a re-ATI event can also be issued by the master by setting the REDO_ATI bit. It will clear automatically after the ATI event was started. 8.10 RF Detection In cases of extreme RF interference, the onchip RF detection is suggested. This detector can be enabled by setting the Noise_Detect bit in the PROX_SETTINGS1 register. By connecting a suitable antenna to the RF pin, it allows the device to detect RF noise and notify the master of possible corrupt data. ii ATI function will use user selected CS_SIZE and PROJ_BIAS (if applicable) and will only adjust the MULTIPLIER bits to reach the base values. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 29 of 48 October 2018 IQ Switch® ProxSense® Series 9 Communication The IQS213A can communicate on the I2C compatible bus structure. It uses a 3-wire serial interface bus which is I2C compatible and comprise of a data (SDA), clock (SCL) and optional ready (RDY) line (for IQS213A pin-out refer to Figure 4.1). The IQS213A has one available I2C address, I2C address = 0x44H. 2 The maximum I C compatible communication speed for the IQS213A is 400kbit/s. 9.1 Event Mode 9.2.2 WDT The WDT is used to reset the IC if a problem (for example a voltage spike) occurs during communication. The WDT will time-out after tWDT, if no valid communication occurs for this time. 9.3 I2C Read and Write specifics For more details, please refer to the IQS213A Memory Map (Section 10) for device memory register descriptions and application note: “AZD066: IQS213 Communication Interface Guideline” document available at: www.azoteq.com. The IQS213A will by default be configured to only communicate with the master if a change in an event occurs. For this reason, it would be highly recommended to use the RDY line when communicating with the IQS213A, especially in Low Power (LP) modes. These communication requests are referred to as Event Mode triggering (only changes in events are reported). Event mode can be disabled by setting the EVENT_MODE_OFF bit. The events responsible for resuming communication can be chosen through the EVENT_MASK register. By default all events are enabled. The device can also communicate on polling basis, using only the SDA and SCL lines. 9.2 I2C Specific commands 9.2.1 IC Reset indication SHOW_RESET can be read to determine whether a reset occurred on the device. This bit will be a ‘1’ after a reset. The value of SHOW_RESET can be cleared to ‘0’ by writing a ‘1’ in the ACK_RESET bit. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 30 of 48 October 2018 IQ Switch® ProxSense® Series 10 IQS213A Memory Map 10.1 Memory Registers Table 10.1 : IQS213A Memory Registers Register Address Register Name Description 00H Product Number ‘D43’ / ‘2BH’ 01H Version Number ‘02’ 10H Sys_flags0 System Flags - See Table 10.2 11H Swipe Flags Swipe Switch Flags - See Table 10.2 35H Touch CHs Channels Touched - See Table 10.2 3DH Chan_num Number of Currently Processed Channel 42H CS High Count (CS) value [high byte] 43H CS Low Count (CS) value [low byte] 83H LTA High Long Term Average [high byte] 84H LTA Low Long Term Average [low byte] C4H Current Sate Swipe Engine Current State C5H Measured State Current Measured State (Acc. to Touches) C6H Next State Swipe Engine Next Expected State C7H Swipe States Combination of States Required for Swipe C8H Swipe Min Timer Minimum timer counts – swipe periods C9H Swipe Max Timer Maximum Overall timer – 250ms periods CAH Swipe Max State Timer Maximum Per State timer – swipe periods CBH Swipe Settings IQS213 Set Up - See Table 10.2 CCH Prox Settings 0 IQS213 Set Up - See Table 10.2 CDH Prox Settings 1 IQS213 Set Up - See Table 10.2 CEH Prox Settings 2 IQS213 Set Up - See Table 10.2 CFH ATI Target CH0 (Target CH0) *8 = Channel 0 Target Value D0H ATI Target CH1-CH3 (Target CH1-CH3) *8 = Channel 1-3 Target Value D1H Prox Threshold Proximity Threshold Value (In Counts) D2H Touch Threshold 1 Channel 1 Touch Threshold [In Counts] Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Device Information Device Specific Data Count Data Device Settings Page 31 of 48 October 2018 IQ Switch® ProxSense® Series Register Address Register Name Description D3H Touch Threshold 2 Channel 2 Touch Threshold [In Counts] D4H Touch Threshold 3 Channel 3 Touch Threshold [In Counts] D5H Base Value ATI Base Value [0-256 - In Counts] D6H Event Mask Events Allowed - See Table 10.2 D7H Mirror_CH0 Mirror – lower 6 bits – NN PPP D8H Mirror_CH1 Mirror – lower 6 bits – NN PPP D9H Mirror_CH2 Mirror – lower 6 bits – NN PPP DAH Mirror_CH3 Mirror – lower 6 bits – NN PPP DBH PCC0 CH0 Compensation DCH PCC1 CH1 Compensation DDH PCC2 CH2 Compensation DEH PCC3 CH3 Compensation DFH AAOW Timer (AAOW Timer)*30s = Auto-Off Warning time E0H AO Timer (AO Timer)*30s = Auto-Off time E1H Swipe Min Samples Set minimum samples per state [x+1] E2H Swipe Max Samples Set maximum samples per state [x+1] E3H Swipe Overall Limit Set Overall Swipe Length Limit [*250ms] E4H LP Period (LP Period)*16ms = Low Power Charge Timing (tLP) E5H Touch States 0 Swipe Engine Configuration E6H Touch States 1 Swipe Engine Configuration E7H Touch States 2 Swipe Engine Configuration E8H Touch States 3 Swipe Engine Configuration E9H Touch States 4 Swipe Engine Configuration EAH Touch States 5 Swipe Engine Configuration EBH Touch States6 Swipe Engine Configuration ECH Touch States 7 Swipe Engine Configuration EDH Default Comms Default Comms pointer Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Device Settings Device Settings Page 32 of 48 October 2018 IQ Switch® ProxSense® Series Table 10.2 : IQS213A Memory Register bits bit7 bit6 bit5 bit4 bit3 bit2 bit1 bit0 Prox Settings 0 Show Reset ACK Reset Reseed Redo ATI ATI Partial Float CX THALT1 THALT0 Prox Settings 1 Comms WDT OFF Event Mode OFF Debug I2C AO Clear Prox AO OFF ACF OFF ATI OFF Noise Detect OFF IO_OUT CS_Cap Proj_B1 Proj_B0 Prox Settings 2 Swipe Settings Swipe Flags Set_3CH Touches/P ulses Swipe UI Swipe UI End_Zero Zero_State States Relaxed Swipe Active Swipe Pulse Flag Time Out Flag Slide Occurred DualSwipe Active Swipe Direction AO Triggered Final State Start State Noise Event ATI Event Swipe Event Touch Event Prox Event Projected CapSense Filter Halt ATI Busy Noise Found Zoom CH3 CH2 CH1 CH0/Prox Event Mask Sys_flags0 System Use Touch CHs Swipe Output LP Active Active High 10.2 Memory Registers Description 10.2.1 Device Information 00H Product Number (Prod_NR) Access Bit R Value 7 6 4 3 2 1 0 2 1 0 43 (Decimal) 01H   5 Version Number (Ver_NR) Access Bit R Value [00H] PROD_NR : [01H] VER_NR : Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved 7 6 5 4 3 Ver_NR The product number for the IQS213A is 43 (decimal). Device ROM software version number can be read in this byte. IQS213A Datasheet Revision 3.0 Page 33 of 48 October 2018 IQ Switch® ProxSense® Series 10.2.2 Device Specific Data 10H Access R  System Flags (Sys_flags0) Bit 7 6 5 4 3 2 1 0 Name System Use LP Active Active High Projected CapSense Filter Halt ATI Busy Noise Found Zoom [10H] Sys_flags0: bit7: System Use bit6: LP Active – Indicates if device is in a Low Power Mode. bit5: Active High – Bit is set if Output Logic is Active High. bit4: Projected CapSense – Bit is set if Projected Capacitance technology is used. bit3: Filter Halt – Indicates if LTA filters are halted. bit2: ATI Busy – Indicates if ATI algorithm is being performed. bit1: Noise Found – Bit is set if RF noise is detected. (RF Detection must be enabled) bit0: Zoom – Indicates if device is zoomed to Normal Power. 11H  Swipe Switch Flags (Swipe Flags) Access Bit R/W Name [11H] Swipe Flags: Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved 7 Swipe Pulse Flag 6 Time Out Flag 5 4 3 2 1 0 Slide Occurred DualSwipe Active Swipe Direction AO Triggered Final State Start State bit7: Swipe Pulse Flag – Bit is set if Pin7 Output = Pulses bit6: Time Out Flag – Bit is set if Max State Timer is exceeded. bit5: Slide Occurred – Bit is set if Swipe event has occured. (Note: Bit must be cleared manually) bit4: DualSwipe Active – Bit is set if Swipe UI = Dual Swipe. bit3: Swipe Direction – 0 = Forward direction, 1 = Reverse direction. bit2: AO Triggered – Bit is set if Auto-Off Warning has been set. bit1: Final State – Bit is set if Swipe Engine is in Final State. bit0: Start State – Bit is set if Swipe Engine is in Start State. IQS213A Datasheet Revision 3.0 Page 34 of 48 October 2018 IQ Switch® ProxSense® Series 10.2.3 Current Sample (CS) or Count Data 35H Access Bit 7 Name Swipe Output [35H] Touch CHs: bit7: Swipe Output – Bit is toggled on Swipe Events. (Note: This bit corresponds to the IC swipe output (Pin6) and is UI dependent.) bit6: Not used. bit5: Not used. bit4: Not used. bit3: CH3 – Bit is set if a Touch is present on this channel. bit2: CH2 – Bit is set if a Touch is present on this channel. bit1: CH1 – Bit is set if a Touch is present on this channel. bit0: CH0/Prox – Bit is set if a Proximity Event is present. R  Touch/Output Data (Touch CHs) 6 3DH  5 4 3 2 1 0 CH3 CH2 CH1 CH0/Prox Channel Number (Chan_num) Access Bit R Name [3DH] Chan_num: Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved 7 6 5 4 3 2 1 0 Variable: Value between 0x00 and 0x03 bit7:0: The Chan_Num byte indicates which channel’s data is currently available in the CS and LTA bytes: 0 = Ch0 (Distributed PROX channel) 1 = Ch1 (CRX0) 2 = Ch2 (CRX1) 3 = Ch3 (CRX2) IQS213A Datasheet Revision 3.0 Page 35 of 48 October 2018 IQ Switch® ProxSense® Series 42H  Count (CS) Value High byte (CS High) Access Bit R Value [42H] CS High: 7 6 2 1 0 Count (CS) Value Low byte (CS Low) Access Bit R Value [43H] CS Low: 7 6 5 4 3 2 1 0 Variable (Low byte) bit7:0: Count (CS) Value Low Byte of currently processed channel. (See Channel Number.) Long Term Average High byte (LTA High) Access Bit R Value [83H] LTA High: 7 6 5 4 3 2 1 0 Variable (High byte) bit7:0: Long Term Average (LTA) value High Byte of currently processed channel. (See Channel Number.) 84H  3 bit7:0: Count (CS) Value High Byte of currently processed channel. (See Channel Number.) 83H  4 Variable (High byte) 43H  5 Long Term Average Low byte (LTA Low) Access Bit R Value [84H] LTA Low: Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved 7 6 5 4 3 2 1 0 Variable (Low byte) bit7:0: Long Term Average (LTA) value Low Byte of currently processed channel. (See Channel Number.) IQS213A Datasheet Revision 3.0 Page 36 of 48 October 2018 IQ Switch® ProxSense® Series 10.2.4 Device Settings CBH Access R/W  SwipeSwitch Settings (Swipe Settings) Bit Name 7 Set_3CH [CBH] Swipe Settings: bit7: bit6: 6 5 4 Touches/Pulses Swipe UI1 Swipe UI0 3 End_Zero 2 1 0 Zero_State States Relaxed Swipe Active Set_3CH – R/W bit. Set bit to enable 3rd channel (CRX2). Touches/Pulses – Bit indicates/set output on IC pin 7. bit5:4: Swipe UI – Bits indicate/set selected swipe user interface (UI). bit3: End_Zero – R/W bit. (See Section 6.11) bit2: Zero_State – R/W bit. (See Section 6.10) bit1: States Relaxed – R/W bit. (See Section 6.1) bit0: Swipe Active – Bit indicates/set selection of Swipe/Normal Mode IC TYPE. (See Section 6.1) ® CCH  ProxSense Module Settings 0 (Prox Settings 0) Access Bit 7 6 5 4 3 2 1 0 R/W Name Show Reset ACK Reset Reseed Redo ATI ATI Partial Float CX THALT1 THALT0 [CCH] Prox Settings 0: bit7: Show Reset – Bit is set if device was reset. bit6: ACK Reset – Set bit to acknowledge device reset (Setting this bit will clear Show Reset bit). bit5: Reseed – Set bit to reseed LTA filter values. bit4: Redo ATI – Set bit to perform ATI algorithm. bit3: ATI Partial – R/W bit. (See Section 8.9) bit2: Float CX – R/W bit. (See Section 6.3) bit1:0: THALT1:THALT0 – Bits indicate/set LTA halt period. (See Section 6.5) Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 37 of 48 October 2018 IQ Switch® ProxSense® Series ® CDH  ProxSense Module Settings 1 (Prox Settings 1) Access Bit R/W Name 7 Comms WDT OFF [CDH] Prox Settings 1: bit7: 5 Event Mode OFF Debug I2C 4 AO Clear Prox 3 2 1 0 AO OFF ACF OFF ATI OFF Noise Detect OFF Comms WDT OFF – R/W bit. (See Section 9.2) bit6: Event Mode OFF – Set bit to disable Event Mode I2C. bit5: Debug I2C – Bit is set during I2C operation. (Do not clear) bit4: AO Clear Prox – Set bit to clear Auto-OFF timer on Prox. bit3: AO OFF – Set bit to disable Auto-OFF function. bit2: ACF OFF – Bit is set if AC Filter is Disabled. (R/W) bit1: ATI OFF – Set bit to disable Auto-ATI functionality. (See Section 8.9) bit0: Noise Detect OFF – Set bit to disable RF detection. ® CEH  6 ProxSense Module Settings 2 (Prox Settings 2) Access Bit R/W Name 7 6 5 4 3 2 1 0 IO_OUT CS_Cap Proj_B1 Proj_B0 [CEH] Prox Settings 2: bit7: Not used. bit6: Not used. bit5: Not used. bit4: Not used. bit3: IO_OUT – Set bit to enable/disable additional output on PO/TX pin (IC pin 10) during I2C operation. bit2: *CS_Cap – R/W bit for selection of Internal Reference Capacitor size. (0 =29.9pF; 1= 59.8pF) bit1:0 *Proj_B1:Proj_B0 – R/W bits for selection of internal bias current for projected capacitance configurations. *Please Note: It is not recommended to adjust the settings of the internal reference capacitor (Cs) and bias current (i.e. bit2:0) of the ProxSense® Module Settings 2 register. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 38 of 48 October 2018 IQ Switch® ProxSense® Series 2 D6H  I C Debug – Event Mode Event Mask (Event Mask) Access Bit R/W Name [D6H] Event Mask: Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved 7 6 5 4 3 2 1 0 Noise Event ATI Event Swipe Event Touch Event Prox Event bit7: Not used. bit6: Not used. bit5: Not used. bit4: Noise Event – Set bit to mask RF Noise events during Event Mode I2C comms. (Requires RF-detection = Enabled.) bit3: ATI Event – Set bit to mask ATI events during Event Mode I2C comms. bit2: Swipe Event – Set bit to mask Swipe events during Event Mode I2C comms. bit1: Touch Event – Set bit to mask Touch events during Event Mode I2C comms. bit0: Prox Event – Set bit to mask Proximity events during Event Mode I2C comms. IQS213A Datasheet Revision 3.0 Page 39 of 48 October 2018 IQ Switch® ProxSense® Series 10.2.4.1 Swipe timing settings E1H  Swipe Min Samples Access Bit R/W Name 7 6 5 [E1H] Swipe Min Samples: 2 1 0 bit7:0: Minimum number of valid samples required per state of the selected Swipe Sequence = x+1. For default (i.e. 0xE1 = 0x00), Min Swipe samples required per state = 1 per state. 1 Swipe Sample = tSTATE – See Section 6.12 Swipe Max Samples Access Bit R/W Name 7 6 5 4 3 2 1 0 Variable: Default = 0x44 [E2H] Swipe Max Samples: bit7:0: Maximum number of valid samples allowed per state of the selected Swipe Sequence = x+1. For default (i.e. 0xE2 = 0x44), Max Swipe samples allowed per state = 45 per state. 1 Swipe Sample = tSTATE – See Section 6.12 E3H  3 Variable: Default = 0x00 E2H  4 Swipe Overall Limit Access Bit R/W Name 7 [E3H] Swipe Overall Limit: Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved 6 5 4 3 2 1 0 Variable: Default = 0x04 bit7:0: Set Overall Swipe Length Limit = x*250ms For default (i.e. 0xE3 = 0x04), maximum time allowed to complete a valid swipe = 1 second. Swipe Overall Limit overrule sum of Swipe Max Samples IQS213A Datasheet Revision 3.0 Page 40 of 48 October 2018 IQ Switch® ProxSense® Series 11 Electrical Specifications – All Preliminary 11.1 Absolute Maximum Specifications Note: Exceeding these maximum specifications may cause damage to the device. Operating temperature -20°C to 85°C Supply Voltage (VDDHI – VSS) 3.6V Maximum pin voltage Maximum continuous current (specific pins) VDDHI + 0.5V 2mA Pin voltage (Cx) Minimum pin voltage VREG VSS - 0.5V Minimum power-on slope ESD protection (Human Body Model) Maximum pin temperature during soldering 100V/s ±4kV 350°C (5 seconds) Maximum load capacitance – Cx to GND Maximum Rx-Tx Mutual capacitance (Cm) 100pF 9pF 11.2 General Characteristics (Measured at 25°C) Table 11.1 IQS213A General Operating Conditions (a) DESCRIPTION Conditions PARAMETER MIN TYP MAX UNIT VDDHI 1.80 3.30 3.60 V 1.80 ≤ VDDHI ≤ 3.60 VREG 1.63 1.70 1.77 V 2CH Self IIQS213A_NP 145 175 210 μA 150 180 215 μA 3.85 4.65 5.65 μA 3.90 4.70 5.70 μA 2.50 3.00 3.60 μA 2.55 3.10 3.65 μA 1.75 2.10 2.65 μA 1.80 2.20 2.75 μA Supply voltage Internal regulator output Normal Power operating current tLP = N/A 1.80 ≤ VDDHI ≤ 3.60 Low power 1 operating current tLP = 128ms 1.80 ≤ VDDHI ≤ 3.60 1 Low power 2 operating current tLP = 256ms 1.80 ≤ VDDHI ≤ 3.60 1 Low power 3 operating current tLP = 512ms 1.80 ≤ VDDHI ≤ 3.60 1 1. 1 3CH Self 2CH Self 3CH Self 2CH Self 3CH Self 2CH Self 3CH Self IIQS213A LP1 IIQS213A LP2 IIQS213A LP3 CHG FRQ = 500kHz, ATI Target = 320/160, Normal Touch IC, Stand-Alone, Active High Output. Altering the projected current bias settings, reference capacitor (CS) size, number of active channels and ATI Target values will affect the measured current. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 41 of 48 October 2018 IQ Switch® ProxSense® Series Table 11.2 IQS213A Current Consumption (b) DESCRIPTION Conditions Normal Power operating current tLP = N/A 1.80 ≤ VDDHI ≤ 3.60 Low power 1 operating current tLP = 128ms 2 Low power 2 operating current tLP = 256ms 2 Low power 3 operating current tLP = 512ms 2 2. 2 2CH Self PARAMETER IIQS213A_NP 3CH Self 2CH Self IIQS213A LP1 3CH Self 2CH Self IIQS213A LP2 3CH Self 2CH Self IIQS213A LP3 3CH Self MIN TYP MAX UNIT 150 180 210 μA 150 185 215 μA 4.35 4.90 5.75 μA 4.40 4.95 5.80 μA 2.85 3.45 4.10 μA 2.90 3.50 4.15 μA 2.15 2.60 3.15 μA 2.25 2.70 3.25 μA CHG FRQ = 500kHz, ATI Target = 320/160, Event-Mode I2C, 10k Pull-Up’s. Altering the projected current bias settings, reference capacitor (CS) size, number of active channels and ATI Target values will affect the measured current. Table 11.3 IQS213A Current Consumption (c) DESCRIPTION Conditions Normal Power operating current tLP = N/A 1.80 ≤ VDDHI ≤ 3.60 Low power 1 operating current tLP = 128ms 3 Low power 2 operating current tLP = 256ms 3 Low power 3 operating current tLP = 512ms 3 3. 3 2CH Projected PARAMETER MIN TYP MAX UNIT 230 250 μA 235 250 μA 4.30 5.10 5.90 μA 4.35 5.15 6.00 μA 2.65 3.20 3.80 μA 2.70 3.25 3.90 μA 1.85 2.25 2.70 μA 1.90 2.30 2.75 μA IIQS213A_NP 3CH Projected 2CH Projected 3CH Projected 2CH Projected 3CH Projected 2CH Projected 3CH Projected IIQS213A LP1 IIQS213A LP2 IIQS213A LP3 CHG FRQ = 2MHz, ATI Target = 320/160, Stand-Alone, Active High Output. Altering the projected current bias settings, reference capacitor (CS) size, number of active channels and ATI Target values will affect the measured current. Table 11.4 IQS213A Current Consumption (d) DESCRIPTION Conditions Normal Power operating current tLP = N/A 1.80 ≤ VDDHI ≤ 3.60 Low power 1 operating current tLP = 128ms 4 Low power 2 operating current tLP = 256ms 4 Low power 3 operating current tLP = 512ms 4 4. 4 2CH Projected PARAMETER MIN TYP MAX UNIT 230 250 μA 235 260 μA 5.45 6.35 7.50 μA 5.60 6.50 7.60 μA 3.30 3.95 4.65 μA 3.40 4.00 4.75 μA 2.40 2.90 3.40 μA 2.50 3.00 3.45 μA IIQS213A_NP 3CH Projected 2CH Projected 3CH Projected 2CH Projected 3CH Projected 2CH Projected 3CH Projected IIQS213A LP1 IIQS213A LP2 IIQS213A LP3 CHG FRQ = 2MHz, ATI Target = 640/320, Event-Mode I2C, 10k Pull-Up’s. Altering the projected current bias settings, reference capacitor (CS) size, number of active channels and ATI Target values will affect the measured current. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 42 of 48 October 2018 IQ Switch® ProxSense® Series Table 11.5 Start-up and shut-down slope Characteristics DESCRIPTION Conditions POR PARAMETER VDDHI Slope ≥ 100V/s BOD MIN MAX UNIT POR 1 1.55 V BOD 1 1.5 V Table 11.6 Debounce employed on IQS213A DESCRIPTION Conditions Debounce Value Proximity debounce value Proximity event 4 (Up and Down) Touch debounce value Touch event 2 (Up and Down) 11.3 Timing Characteristics Table 11.7 Main Oscillator SYMBOL FOSC 1. DESCRIPTION IQS213A Main oscillator Conditions 1 MIN TYP 1.80 ≤ VDDHI ≤ 3.60 MAX UNIT 4 MHz All timings derived from Main Oscillator Table 11.8 General Timing Characteristics for 1.80V ≤ VDDHI ≤ 3.60V SYMBOL DESCRIPTION Conditions tSTART-UP Start-up time before the first communication is initiated by the IQS213A fCX Charge transfer frequency tCHARGE Charge time per channel tCHANNEL Stand-alone / I C Mode TYP MAX UNIT 15 ms See CHG_FRQ in Section 8.3 MHz CS * (1/fCX) ms Normal Power 2 tSAMPLE tWDT MIN 2.6 / 3.9 ms Active channels * tCHANNEL ms 160 ms WDT time-out while communicating Table 11.9 IQS213A Charging Times TYPICAL (ms) POWER MODE Standalone I2C Normal Power Mode 2.6 3.9 Low Power Mode 1 128 128 Low Power Mode 2 256 256 Low Power Mode 3 512 512 **NOTE: with ACF = ON, “wake-on-prox” times will increase due to the CS having to go through an additional filtering process adding a delay. Please refer to “Application Note AZD079 – IQS213 Touch response rate” for more information. Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 43 of 48 October 2018 IQ Switch® ProxSense® Series 12 Packaging Information Figure 12.1 MSOP-10 Package Dimensions MSOP-10 PCB Footprint Dimensions: Dimension Pitch C Y X Figure 12.2 Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved [mm] 0.50 4.40 1.45 0.30 MSOP-10 PCB Footprint IQS213A Datasheet Revision 3.0 Page 44 of 48 October 2018 IQ Switch® ProxSense® Series 12.1 Tape and Reel Specification Figure 12.5 MSOP-10 Tape Specification. Bulk orientation LT 12.2 Package MSL 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 JSTD033C for more info) before reflow occur. Table 12.1 MSOP-10 MSL classification Package Level (duration) MSL 1 (Unlimited at ≤30 °C/85% RH) MSOP-10 Reflow profile peak temperature < 260 °C for < 25 seconds Number of Reflow ≤ 3 Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 45 of 48 October 2018 IQ Switch® ProxSense® Series 13 Device Marking 13.1 Top marking IC NAME IQS213A = IQS213A REVISION x = IC Revision Number TEMPERATURE RANGE t = = i c DATE CODE P = Package House WW = Week YY = Year -20°C to 85°C (Industrial) 0°C to 70°C (Commercial) 13.2 Bottom Marking zzzzzzzz Configuration Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved zzzzzzzz = Device Configuration / User Programmable Options [Default = 00000000] IQS213A Datasheet Revision 3.0 Page 46 of 48 October 2018 IQ Switch® ProxSense® Series 14 Ordering Information Orders will be subject to a MOQ (Minimum Order Quantity) 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. 14.1 General Part Order Number IQS213A zzzzzzzz pp b IC NAME IQS213A = IQS213A CONFIGURATION zzzzzzzz = User Programmable Option Selection PACKAGE TYPE MS = MSOP10 BULK PACKAGING R = Reel (4000pcs/reel) Copyright © Azoteq (Pty) Ltd 2018 All Rights Reserved IQS213A Datasheet Revision 3.0 Page 47 of 48 October 2018 IQ Switch® ProxSense® Series Azoteq USA Asia South Africa Physical Address 11940 Jollyville Suite 120-S Austin TX 78750 USA Room 501A, Block A, T-Share International Centre, Taoyuan Road, Nanshan District, Shenzhen, Guangdong, PRC 1 Bergsig Avenue Paarl 7646 South Africa Postal Address 11940 Jollyville Suite 120-S Austin TX 78750 USA Room 501A, Block A, T-Share International Centre, Taoyuan Road, Nanshan District, Shenzhen, Guangdong, PRC PO Box 3534 Paarl 7620 South Africa Tel +1 512 538 1995 +86 755 8303 5294 ext 808 +27 21 863 0033 Email info@azoteq.com info@azoteq.com info@azoteq.com Visit www.azoteq.com for a list of distributors and worldwide representation. Patents as listed on www.azoteq.com/patents-trademarks/ may relate to the device or usage of the device. Azoteq®, Crystal Driver , IQ Switch®, ProxSense®, ProxFusion®, LightSense™, SwipeSwitch™, 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 informat ion for any purpose. 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 o r caused by, without limitation, failure of performance, error, omission, interruption, defect, delay in operation or transmiss ion, even if Azoteq has been advised of the possibility of such damages. The applications mentioned herein are used solely for the purpose of illustration and Azoteq makes no warranty or representation that such applications will be suitable without further modification, nor recommends the use of its products for application that may present a risk to human life due to malfunction o r otherwise. Azoteq products are not authorized for use as critical components in life support devices or systems. No licenses to patents are granted, implicitly, express or implied, by estoppel or otherwise, under any intellectual property rights. In the event that any of the abovementioned limitations or exclusions does not apply , it is agreed that Azoteq’s total liability for all losses, damages and causes of action (in contract, tort (including without limitation, negligence) or otherwise) will not exceed the amount already paid by the customer for the products. Azoteq reserves the right to alter its products, to make corrections, deletions, modifications, enhancements, improvements and other changes to the content and information, its products, programs and services at any time or to move or discontinue any contents, products, programs or services without pr ior notification. For the most up-to-date information and binding Terms and Conditions please refer to www.azoteq.com. Copyright © Azoteq (Pty) Ltd 2019. All Rights Reserved. info@azoteq.com IQS5xx-B000 Datasheet Revision 2.1 Page 1 of 1 March 2021