QT1080 lQ z 100% autocal for life - no adjustments required z Direct outputs - either encoded or ‘per key’ z Fully debounced results z 2.8V ~ 5.0V single supply operation z 45µA current typ @ 3V in 360ms LP mode z AKS™ Adjacent Key Suppression SNS5K SNS6 SNS6K SNS7 SNS7K z Designed for low-power portable applications VSS DETECT z Eight completely independent QT touch sensing fields SYNC/LP 8 KEY QTOUCH™ SENSOR IC 24 23 22 21 20 19 18 17 OUT_0 25 16 SNS5 OUT_1 26 15 SNS4K OUT_2 27 OUT_3 28 OUT_4 29 12 SNS3 OUT_5 30 11 SNS2K OUT_6 31 10 SNS2 OUT_7 32 9 SN1K QT1080 32-QFN 14 SNS4 13 SNS3K 2 3 4 5 6 7 8 VDD OSC N.C. SNS0 SNS0K SNS1 z 10ms ‘fast mode’ for use in slider applications 1 SS z Sync pin for excellent LF noise rejection /RST z Spread spectrum bursts for superior noise rejection z RoHS compliant packages: 32-QFN and 48-SSOP APPLICATIONS MP3 players Mobile phones PC peripherals Television controls Pointing devices Remote controls QT1080 charge-transfer (’QT’) QTouch IC is a self-contained digital controller capable of detecting near-proximity or touch on up to eight electrodes. It allows electrodes to project independent sense fields through any dielectric such as glass or plastic. This capability coupled with its continuous self-calibration feature can lead to entirely new product concepts, adding high value to product designs. The devices are designed specifically for human interfaces, like control panels, appliances, gaming devices, lighting controls, or anywhere a mechanical switch or button may be found; they may also be used for some material sensing and control applications. Each of the channels operates independently of the others, and each can be tuned for a unique sensitivity level by simply changing a corresponding external Cs capacitor. AKS™ Adjacent Key Suppression (patent pending) suppresses touch from weaker responding keys and allows only a dominant key to detect, for example to solve the problem of large fingers on tightly spaced keys. Spread spectrum burst technology provides superior noise rejection. These devices also have a SYNC/LP pin which allows for synchronization with additional similar parts and/or to an external source to suppress interference, or, an LP (low power) mode which conserves power. By using the charge transfer principle, this device delivers a level of performance clearly superior to older technologies yet is highly cost-effective. This part is available in both 32-QFN and 48-SSOP RoHS compliant packages. TA AVAILABLE OPTIONS 32-QFN 48-SSOP -40ºC to +85ºC QT1080-ISG QT1080-IS48G LQ Copyright © 2004-2006 QRG Ltd QT1080 R11.04/0206 1 Overview Spread Spectrum operation: The bursts operate over a spread of frequencies, so that external fields will have minimal effect on key operation and emissions are very weak. Spread spectrum operation works with the DI mechanism to dramatically reduce the probability of false detection due to noise. 1.1 Parameters The QT1080 is an easy to use, eight-touch-key sensor IC based on Quantum’s patented charge-transfer principles for robust operation and ease of design. This device has many advanced features which provide for reliable, trouble-free operation over the life of the product. Sync Mode: The QT1080 features a Sync mode to allow the device to slave to an external signal source, such as a mains signal (50/60Hz), to limit interference effects. This is performed using the SYNC/LP pin. Sync mode operates by triggering two sequential acquire bursts, in sequence A-B from the Sync signal. Thus, each Sync pulse causes all eight keys to be acquired. Burst operation: The device operates in ‘burst mode’. Each key is acquired using a burst of charge-transfer sensing pulses whose count varies depending on the value of the reference capacitor Cs and the load capacitance Cx. In LP mode, the device sleeps in an ultra-low current state between bursts to conserve power. The keys signals are acquired using two successive bursts of pulses: Low Power (LP) Mode: The device features an LP mode for microamp levels of current drain with a slower response time, to allow use in battery operated devices. On touch detection, the device automatically reverts to its normal mode and asserts the DETECT pin active to wake up a host controller. The device remains in normal, full acquire speed mode until another pulse is seen on its SYNC/LP pin, upon which it goes back to LP mode. Burst A: Keys 0, 1, 4, 5 Burst B: Keys 2, 3, 6, 7 Bursts always operate in A-B sequence. Self-calibration: On power-up, all eight keys are self-calibrated within 350 milliseconds (typical) to provide reliable operation under almost any conditions. AKS™ Adjacent Key Suppression is a patent-pending feature that can be enabled via jumper resistors. AKS works to prevent multiple keys from responding to a single touch, a common complaint about capacitive touch panels. This can happen with closely spaced keys, or with control surfaces that have water films on them. Auto-recalibration: The device can time out and recalibrate each key independently after a fixed interval of continuous touch detection, so that the keys can never become ‘stuck on’ due to foreign objects or other sudden influences. After recalibration the key will continue to function normally. The delay is selectable to be either 10s, 60s, or infinite (disabled). AKS operates by comparing signal strengths from keys within a group of keys to suppress touch detections from those that have a weaker signal change than the dominant one. The device also auto-recalibrates a key when its signal reflects a sufficient decrease in capacit ance. In this case the device recalibrates after ~2 seconds so as to recover normal operation quickly. The QT1080 has two different AKS groupings of keys, selectable via option resistors. These groupings are: y AKS operates in two groups of four keys. Drift compensation operates to correct the reference level of each key slowly but automatically over time, to suppress false detections caused by changes in temperature, humidity, dirt and other environmental effects. y AKS operates over all eight keys. These two modes allow the designer to provide AKS while also providing for shift or function operations. The drift compensation is asymmetric; in the increasing capacitive load direction the device drifts more slowly than in the decreasing direction. In the increasing direction, the rate of compensation is one count of signal per two seconds; in the opposing direction, it is one count every 500ms. If AKS is disabled, all keys can operate simultaneously. Outputs: There are two output modes: one per key, and binary coded. One per key outputs: In this mode there is one output pin per key. This mode has two output drive options, push-pull and open-drain. The outputs can also be made either active-high or active-low. These options are set via external configuration resistors. Detection Integrator (DI) confirmation reduces the effects of noise on the QT1080 outputs. The ‘detect integrator’ mechanism requires consecutive detections over a number of measurement bursts for a touch to be confirmed and indicated on the outputs. In a like manner, the end of a touch (loss of signal) has to be confirmed over a number of measurement bursts. This process acts as a type of ‘debounce’ against noise. Binary coded outputs: In this mode, three output lines encode for one possible key in detect. If more than one key is detecting, only the first one touched will be indicated. Simplified Mode: To reduce the need for option resistors, the simplified operating mode places the part into fixed settings with only the AKS feature being selectable. LP mode is also possible in this configuration. Simplified mode is suitable for most applications. In normal operation, both the start and end of a touch must be confirmed for six measurement bursts. In a special ‘Fast Detect‘ mode (available via jumper resistors), confirmation of the start of a touch requires only two sequential detections, but confirmation of the end of a touch is still six bursts. Fast detect is only available when AKS is disabled. lQ 2 QT1080 R11.04/0206 1.1 Wiring Table 1.1 Pinlist 32-QFN Pin 48-SSOP Pin Name Type Function Notes If Unused 1 2 3 33 34 35 36 SS n/c /RST Vdd OD I Pwr Spread spectrum Reset input Power 100K resistor to Vss Vdd - 4 37 OSC I Oscillator Spread spectrum drive Leave open Active low reset +2.8 ~ +5.0V Resistor to Vdd and optional spread spectrum RC network 5 38, 39, 40, 41, 42 n/c - - 6 43 SNS0 I/O 7 44 SNS0K I/O 8 45 SNS1 I/O 9 46 SNS1K I/O - Leave open Sense pin and option select Sense pin Sense pin and option select Sense pin Sense pin and option select Sense pin Sense pin and option select Sense pin Sense pin and option select Sense pin Sense pin and option select Sense pin Sense pin and option select Sense pin and mode select To Cs0 and/or option resistor To Cs0 + Key To Cs1 and/or option resistor* To Cs1 + Key To Cs2 and/or option resistor* To Cs2 + Key To Cs3 and/or option resistor* To Cs3 + Key To Cs4 and/or option resistor* To Cs4 + Key To Cs5 and/or option resistor* To Cs5 + Key To Cs6 and/or option resistor* To Cs6 + Key and/or mode resistor† - Option resistor 12 1 SNS3 I/O 13 2 SNS3K I/O 14 3 SNS4 I/O 15 4 SNS4K I/O 16 5 SNS5 I/O 17 6 SNS5K I/O 18 7 SNS6 I/O 19 8 SNS6K I/O 20 9 SNS7 I/O Sense pin and mode or option select To Cs7 and/or mode resistor† or option resistor* 21 10 11, 12, 13, 14, 15, 16 17 18, 19, 20 21 22 23, 24 25 26 27 28 29 30 31 32 SN7K I/O Sense pin To Cs7 + Key Open Open or option resistor* Open Open or option resistor* Open Open or option resistor* Open Open or option resistor* Open Open or option resistor* Open Open or option resistor* Open or mode resistor† Open or mode resistor† or option resistor* Open n/c - - Leave open - Vss n/c SYNC/LP‡ DETECT n/c OUT_0 OUT_1 OUT_2 OUT_3 OUT_4 OUT_5 OUT_6 OUT_7 Pwr I O/OD O/OD O/OD O/OD O/OD O/OD O/OD O/OD O/OD Ground Sync In or LP In Detect Status Out 0 Out 1 Out 2 Out 3 Out 4 Out 5 Out 6 Out 7 0V Leave open Rising edge sync or LP pulse Active = any key in detect Leave open Also, binary coded output 0 Also, binary coded output 1 Also, binary coded output 2 Vdd or Vss Open Open Open Open Open Open Open Open Open 10 47 SNS2 I/O 11 48 SNS2K I/O 22 23 24 25 26 27 28 29 30 31 32 In binary coded mode, these pins are clamped internally to Vss Pin Type I I/O O OD O/OD Pwr CMOS input only CMOS I/O CMOS push-pull output CMOS open drain output CMOS push pull or open-drain output (option selected) Power / ground Notes † Mode resistor is required only in Simplified mode (see Figure 1.2) * Option resistor is required only in Full Options mode (see Figure 1.1) ‡ Pin is either Sync or LP depending on options selected (functions SL_0, SL_1, see Figure 1.1) lQ 3 QT1080 R11.04/0206 Figure 1.1 Connection Diagram - Full Options; Shown for 32-QFN Package VDD +2.8 ~ +5V Voltage Reg Vunreg *4.7uF *4.7uF *100nF 3 2.2K RSNS3 4.7nF KEY 3 CS3 RS3 4.7nF KEY 4 13 1M 2.2K 4.7nF KEY 5 CS5 R S5 4.7nF KEY 6 CS6 RS6 1M SL_0 Vdd / Vss 1M 2.2K 10K RSNS7 OUT_D Vdd / Vss 2.2K 10K RSNS6 4.7nF KEY 7 /RST SNS3 SNS3K SNS4 POL CS4 RS4 Vdd / Vss 10K RSNS5 1M 2.2K 10K RSNS4 12 MOD_1 Vdd / Vss 2 VDD SL_1 CS7 RS7 Vdd / Vss 1M 15 SNS4K 16 SNS5 17 SNS5K 18 SNS6 SNS2K 11 SNS2 10 SNS1K 9 SNS1 8 SNS0K 7 SNS0 6 SNS6K 20 SNS7 21 SNS7K 24 DETECT OUT 2.2K OSC Rb2 SS VSS SYNC/LP DETECT Vdd Range 2.8 ~ 3.59V 3.6 ~ 5V 1 Rb2 22K 27K OUT_7 32 OUT_7 OUT_6 31 OUT_6 OUT_5 30 OUT_5 OUT_4 29 OUT_4 OUT_3 28 OUT_3 OUT_2 27 OUT_2 OUT_1 26 OUT_1 OUT_0 25 OUT_0 AKS MODE Off Off On, in 2 groups On, global Table 1.3 Max On-Duration MOD_1 Vss Vss Vdd Vdd MOD_0 Vss Vdd Vss Vdd MAX ON-DURATION MODE 10 seconds (nom) to recalibrate 60 seconds (nom) to recalibrate Infinite (disabled) (reserved) Table 1.4 OUT_D Vss Vss Vdd Vdd POL Vss Vdd Vss Vdd OUT_n, DETECT PIN MODE Binary coded, active high, push-pull Direct, active low, open-drain Direct, active high, push-pull Direct, active low, push-pull SL_1 Vss Vss Vdd Vdd SL_0 Vss Vdd Vss Vdd SYNC/LP PIN MODE Sync LP mode: 110ms nom response time LP mode: 200ms nom response time LP mode: 360ms nom response time 4 Rb1 12K 15K 100nF AKS_0 Vss Vdd Vss Vdd lQ KEY 0 10K CS0 AKS_1 Vss Vss Vdd Vdd Table 1.5 SYNC/LP Function RSNS0 4.7nF RS0 Table 1.2 AKS / Fast-Detect Options Polarity and Output KEY 1 10K CS1 Recommended Rb1, Rb2 Values Rb1 4 QT1080 32-QFN 23 RS1 AKS_0 Vdd / Vss RSNS1 4.7nF VDD 10K SYNC or LP IN 2.2K 1M 10K CS2 AKS_1 Vdd / Vss 1M KEY 2 RS2 2.2K 19 22 RSNS2 4.7nF MOD_0 Vdd / Vss 1M FAST-DETECT Off Enabled Off Off QT1080 R11.04/0206 Figure 1.2 Connection Diagram - Simplified Mode; Shown for 32-QFN SMR resistor installed between SNS6K and SNS7. VDD +2.8 ~ +5V Voltage Reg Vunreg *4.7uF *4.7uF *100nF 3 RS3 RSNS3 4.7nF KEY 3 CS3 KEY 4 RSNS5 4.7nF KEY 6 RS5 CS5 KEY 7 2.2K RS6 2.2K CS6 SNS3K CS7 15 SNS4K 16 SNS5 17 SNS5K 18 SNS6 19 SNS6K 20 SNS7 21 SNS7K SMR RS7 10K RSNS7 4.7nF 2.2K CS4 10K RSNS6 4.7nF 13 SNS3 2 /RST SNS4 10K KEY 5 2.2K RS4 10K RSNS4 4.7nF 12 VDD 1M 2.2K SNS2K 11 SNS2 10 SNS1K 9 SNS1 8 SNS0K 7 SNS0 6 23 24 DETECT OUT Table 1.6 AKS Resistor Options AKS_0 Vss Vdd 2.2K 2.2K AKS_0 Vdd / Vss RSNS1 4.7nF RS1 1M KEY 1 10K CS1 RSNS0 4.7nF KEY 0 RS0 10K CS0 2.2K Recommended Rb1, Rb2 Values Rb1 OSC Rb2 SS VSS SYNC/LP DETECT AKS MODE Off On, global Vdd Range 2.8 ~ 3.59V 3.6 ~ 5V 4 QT1080 32-QFN LP IN KEY 2 10K CS2 VDD 10K 22 RSNS2 4.7nF RS2 1 Rb1 12K 15K Rb2 22K 27K 100nF OUT_7 32 OUT_7 OUT_6 31 OUT_6 OUT_5 30 OUT_5 OUT_4 29 OUT_4 OUT_3 28 OUT_3 OUT_2 27 OUT_2 OUT_1 26 OUT_1 OUT_0 25 OUT_0 FAST-DETECT Enabled Off Table 1.7 Functions in Simplified Mode Output Drive, Polarity SYNC/LP pin Max on-duration delay Detect Pin lQ Direct outputs, push-pull, active high 200ms nom LP function; sync not available 60 seconds (nom) Active high on any detect 5 QT1080 R11.04/0206 2 Device Operation 2.5 DETECT Pin DETECT represents the functional logical-OR of all eight keys. DETECT can be used to wake up a battery-operated product upon human touch. 2.1 Startup Time After a reset or power-up event, the device requires 350ms to initialize, calibrate, and start operating normally. Keys will work properly once all keys have been calibrated after reset. DETECT is also required to indicate to a host when the binary coded output pins (in that mode) are showing an active key. While DETECT is active, the binary coded outputs should be read at least twice along with DETECT to make sure that the code was not transition ing between states, to prevent a false reading. 2.2 Option Resistors The option resistors are read on power-up only. There are two primary option mode configurations: full, and simplified. The output polarity and drive of DETECT are governed according to Table 1.4. In full options mode, eight 1M✡ option resistors are required as shown in Figure 1.1. All eight resistors are mandatory. To obtain simplified mode, a 1M✡ resistor should be connected from SNS6K to SNS7. In simplified mode, only one additional 1M✡ option resistor is required for the AKS feature (Figure 1.2). 2.6 SYNC/LP Pin Note that the presence and connection of option resistors will affect the required values of Cs; this effect will be especially noticeable if the Cs values are under 22nF. Cs values should be adjusted for optimal sensitivity after the option resistors are connected. Sync mode: Sync allows the designer to synchronize acquire bursts to an external signal source, such as mains frequency (50/60 Hz) to suppress interference. It can also be used to synchronize two QT parts which operate near each other, so that they will not cross-interfere if two or more of the keys (or associated wiring) of the two parts are near each other. The SYNC / LP pin function is configured according to the SL_0 and SL_1 resistor connections to either Vdd or Vss , according to the Table 1.5. 2.3 OUT Pins - Direct Mode Direct output mode is selected via option resistors, as shown in Table 1.4. The SYNC input of the QT1080 is positive pulse triggered. If the SYNC input does not change, the device will free-run at its own rate after ~150ms. In this mode, there is one output for each key; each is active when a touch is confirmed on the corresponding electrode. Unused OUT pins should be left open. A trigger pulse on SYNC will cause the device to fire two acquire bursts in A-B sequence: If AKS is off, it is possible for all OUT pins to be active at the same time. Burst A: Keys 0, 1, 4, 5 Burst B: Keys 2, 3, 6, 7 Circuit of Figure 1.1: OUT polarity and drive are governed by the resistor connections to Vdd or Vss according to Table 1.4. The drive can be either push-pull or open-drain, active low or high. Low Power LP Mode: This allows the device to enter a slow mode with very low power consumption, in one of three response time settings: 110ms, 200ms, and 360ms nominal . LP mode is entered by a positive >150µs trigger pulse on the SYNC/LP pin. Once the LP pulse is detected , the device will enter and remain in this microamp mode until it senses and confirms a touch Then it will switch back to normal (full speed) mode on its own, with a response time of 30ms typical (burst length dependent). The device will go back to LP mode again if SYNC/LP is held high, or after another LP pulse is received. Circuit of Figure 1.2: In this simplified circuit, the OUT pins are active high, push-pull only. 2.4 OUT Pins - Binary Coded Mode Binary code mode is selected via option resistors, as shown in Table 1.4. In this mode, a key detection is registered as a binary code on pins OUT_2, OUT_1 and OUT_0, with possible values from 000 to 111. In practice, four lines are required to read the code, unless key 0 is not implemented: the output code 000 can mean either ‘nothing detecting’ or ‘key 0 is detecting’. The fourth required line (if all eight keys are implemented) is the DETECT signal, which is active-high when any key is active. The response time setting is determined by option resistors SL_1 and SL_0; see Table 1.5. Slower response times result in lower power drain. The SYNC/LP pulse should be >150µs in duration. If the SYNC/LP pin is held high permanently, the device will go into normal mode during a key touch, and return to low-current mode when the detection ceases. The first key touched always wins and shows its output. Keys that come afterwards are hidden until the currently reported key has stopped detecting, in which case the code will change to the latent key. If the SYNC/LP pin is held low constantly, the device will remain in normal mode (25ms typical response time) continuously. This mode is useful to reduce the number of connections to a host controller, at the expense of being able to only report one active key at a time. Note that in global AKS mode (Section 2.7), only one key can report active at a time anyway. Circuit of Figure 1.1: OUT polarity and drive can only be push-pull and active high. Circuit of Figure 1.2: Binary coded not available. lQ 6 QT1080 R11.04/0206 AKS in this mode is Global only (i.e. operates across all functioning keys). 2.7 AKS™ Function Pins The QT1080 features an adjacent key suppression ( AKS™) function with two modes. Option resistors act to set this feature according to Tables 1.2 and 1.6. AKS can also be disabled, allowing any combination of keys to become active at the same time. When operating, the modes are: The other option features are fixed as follows: OUT_n, DETECT Pins: Push-pull, active high, direct outputs SYNC/LP Function: LP mode, ~200ms response time Max On-Duration: 60 seconds See Tables 1.6 and 1.7. Global: AKS functions operates across all eight keys. This means that only one key can be active at any one time. Groups: AKS functions among two groups of four keys: 0-1-4-5 and 2-3-6-7. This means that up to two keys can be active at any one time. 2.11 Unused Keys Unused keys should be disabled by removing the corresponding Cs, Rs, and Rsns components and connecting SNS pins as shown in the ‘Unused’ column of Table 1.1. Unused keys are ignored and do not factor into the AKS function (Section 2.7). In Group mode, keys in one group have no AKS interaction with keys in the other group. Note that in Fast Detect mode, AKS can only be off. 2.8 MOD_0, MOD_1 Inputs In full option mode, MOD_0 and MOD_1 resistors are used to set the ‘Max On-Duration’ recalibration timeouts. If a key becomes stuck on for a lengthy duration of time, this feature will cause an automatic recalibration event of that specific key only once the specified on-time has been exceeded. Settings of 10s, 60s, and infinite are available. 3 Design Notes 3.1 Oscillator Frequency The QT1080’s internal oscillator runs from an external resistor network connected to the OSC and SS pins as shown in Figures 1.1 and 1.2 to achieve spread spectrum operation. If spread spectrum mode is not required, the OSC pin should be connected to Vdd with an 18K ohm 1% resistor. The Max On-Duration feature operates on a key-by-key basis; when one key is stuck on, its recalibration has no effect on other keys. The logic combination on the MOD option pins sets the timeout delay; see Table 1.3. Under different Vdd voltage conditions the resistor network (or the solitary 18K ohm resistor) might require minor adjustment to obtain the specified burst center frequency. The network should be adjusted slightly so that the positive pulses on any key are approximately 2µs wide in the ‘solitary 18K resistor’ mode, or 2.15µs wide at the beginning of a burst with the recommended spread spectrum circuit (see next section). Simplified mode MOD timing: In simplified mode, the max on-duration is fixed at 60 seconds. 2.9 Fast Detect Mode In many applications, it is desirable to sense touch at high speed. Examples include scrolling ‘slider’ strips or ‘Off’ buttons. It is possible to place the device into a ‘Fast Detect’ mode that usually requires under 1 0ms to respond. This is accomplished internally by setting the Detect Integrator to only two counts, i.e. only two successive detections are required to detect touch. In practice, the pulse width has little effect on circuit performance if it varies in the range from 1.5µs to 2.5µs. The only effects will be seen in non-LP mode, as proportional variations in Max On-Duration times and response times. In LP mode, ‘Fast’ detection will not speed up the initial delay (which could be up to 360ms nominal depending on the option setting). However, once a key is detected the device is forced back into normal speed mode . It will remain in this faster mode until another LP pulse is received. 3.2 Spread Spectrum Circuit The QT1080 offers the ability to spectrally spread its frequency of operation to heavily reduce susceptibility to external noise sources and to limit RF emissions. The SS pin is used to modulate an external passive RC netw ork that modulates the OSC pin. OSC is the main oscillator current input. The circuit is shown in both Figures 1.1 and 1.2. When used in a ‘slider’ application, it is normally desirable to run the keys without AKS. In both normal and ‘Fast’ modes, the time required to process a key release is the same . It takes six sequential confirmations of non-detection to turn a key off. The resistors Rb1 and Rb2 should be changed depending on Vdd. As shown in Figures 1.1 and 1.2, two sets of values are recommended for these resistors depending on Vdd. The power curves in Section 4.6 also show the effect of these resistors. Fast Detect mode can be enabled as shown in Tables 1.2 and 1.6. The circuit can be eliminated , if it is not desired, by using an 18K ohm resistor from OSC to Vdd to drive the oscillator, and connecting SS to Vss with a 100K ohm resistor. This mode consumes significantly less current than spread spectrum mode. 2.10 Simplified Mode A simplified operating mode which does not require the majority of option resistors is available. This mode is set by connecting a resistor labelled SMR between pins SNS6K and SNS7; see Figure 1.2. The spread-spectrum RC network might need to be modified slightly if the burst lengths are particularly long. Vdd variations can shift the center frequency and spread slightly. In this mode there is only one option possible - AKS enable or disable. When AKS is disabled, Fast Detect mode is enabled; when AKS is enabled, Fast Detect mode is off. lQ 7 QT1080 R11.04/0206 The required values of Cs can be noticeably affected by the presence and connection of the option resistors (see Section 2.2). The sawtooth waveform observed on SS should reach a crest height as follows: Vdd >= 3.6V: 17% of Vdd Vdd < 3.6V: 20% of Vdd 3.4 Power Supply The 100nF capacitor connected to SS (Figures 1.1 and 1.2) should be adjusted so that the wavefor m approximates the above amplitude, ±10%, during normal operation in the target circuit. If this is done, the circuit will give a spectral modulation of 12-15%. The power supply can range from 2.8 to 5. 0 volts. If this fluctuates slowly with temperature, the device will track and compensate for these changes automatically with only minor changes in sensitivity. If the supply voltage drifts or shifts quickly, the drift compensation mechanism will not be able to keep up, causing sensitivity anomalies or false detections. 3.3 Cs Sample Capacitors - Sensitivity The power supply should be locally regulated , using a three-terminal device, to between 2.8V and 5 .0V. If the supply is shared with another electronic system, care should be taken to ensure that the supply is free of digital spikes, sags and surges which can cause adverse effects. The Cs sample capacitors accumulate the charge from the key electrodes and determine sensitivity. Higher values of Cs make the corresponding sensing channel more sensitive. The values of Cs can differ for each channel, permitting differences in sensitivity from key to key or to balance unequal sensitivities. Unequal sensitivities can occur due to key size and placement differences and stray wiring capacitances. More stray capacitance on a sense trace will desensitize the corresponding key; increasing the Cs for that key will compensate for the loss of sensitivity. For proper operation a 0.1µF or greater bypass capacitor must be used between Vdd and Vss ; the bypass capacitor should be routed with very short tracks to the device’s Vss and Vdd pins. 3.5 PCB Layout and Construction The Cs capacitors can be virtually any plastic film or low to medium-K ceramic capacitor. The ‘normal’ Cs range is 2 .2nF to 50nF depending on the sensitivity required; larger values of Cs require better quality to ensure reliable sensing. Acceptable capacitor types for most uses include PPS film, polypropylene film, and NP0 and X7R ceramics. Lower grades than X7R are not advised. lQ Refer to Quantum application note AN-KD02 for information related to layout and construction matters. 8 QT1080 R11.04/0206 4 Specifications 4.1 Absolute Maximum Specifications Operating temperature, Ta. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -40 ~ +85ºC Storage temp, Ts. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -50ºC ~ +125ºC Vdd. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3 ~ +6.0V Max continuous pin current, any control or drive pin. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±20mA Short circuit duration to ground or Vdd, any pin. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . infinite Voltage forced onto any pin. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -0.3V ~ (Vdd + 0.3) Volts 4.2 Recommended Operating Conditions Operating temperature, Ta. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -40 ~ +85ºC VDD. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +2.8 ~ +5.0V Short-term supply ripple+noise. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±5mV/s Long-term supply stability. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±100mV Cs range. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.2nF ~ 100nF Cx range. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0 ~ 50pF 4.3 AC Specifications Vdd = 5.0, Ta = recommended, Cx = 5pF, Cs = 4.7nF; circuit of Figure 1.1 Parameter Description Min Typ Max Units Trc Recalibration time 150 ms Fc Burst center frequency 132 kHz Fm Burst modulation, percent 15 % Tpc Sample pulse duration 2 µs ms Tsu Startup time from cold start 350 Tbd Burst duration 3.4 ms Tdf Response time - Fast mode 10 ms ms Notes Total deviation Both bursts together Tdn Response time - Normal mode 25 Tdl Response time - LP mode 200 ms 200ms LP setting Tdr Release time - all modes 25 ms End of touch 4.4 DC Specifications Vdd = 5.0, Ta = recommended, Cx = 5pF, Cs = 4.7nF; circuit of Figure 1.1 unless noted Parameter Description IDDN Supply current, normal mode* IDDL Supply current, LP mode* VDDS Supply turn-on slope VIL Low input logic level VHL High input logic level VOL Low output voltage VOH High output voltage IIL Input leakage current AR Acquisition resolution Min Typ Max Units 4.5 2.7 2.2 1.8 1.5 1.3 8 mA @ Vdd = 5.0 @ Vdd = 4.0 @ Vdd = 3.6 @ Vdd = 3.3 @ Vdd = 3.0 @ Vdd = 2.8 µA @ Vdd = 3.0; 360ms LP mode V/s Req’d for startup, w/o external reset ckt 45 100 Notes 0.7 V 0.5 V 7mA sink V 2.5mA source 3.5 V Vdd-0.5 ±1 8 µA bits *No spread spectrum circuit; Rosc = 18K ohms 4.5 Signal Processing Vdd = 5.0, Ta = recommended, Cx = 5pF, Cs = 4.7nF Value Units Notes Detection threshold Description 10 counts Threshold for increase in Cx load Detection hysteresis 2 counts Anti-detection threshold 6 counts Anti-detection recalibration delay 2 secs Detect Integrator filter, normal mode 6 samples Must be consecutive or detection fails Detect Integrator filter, ‘fast’ mode 2 samples Must be consecutive or detection fails 10, 60, ∞ secs 2,000 ms/level Towards increasing Cx load 500 ms/level Towards decreasing Cx load Max On-Duration Normal drift compensation rate Anti drift compensation rate lQ 9 Threshold for decrease of Cx load Time to recalibrate if Cx load has exceeded anti-detection threshold Option pin selected QT1080 R11.04/0206 4.6 Idd Curves Cx = 5pF, Cs = 4.7nF, Ta = 20oC, Spread spectrum circuit of Fig. 1.1. QT1080 Idd (110m s response) µA 500 4.0 400 Rb1=15K Rb2=27K 3.0 Idd(µA) Idd(mA) QT1080 Idd (norm al m ode) m A 5.0 2.0 1.0 Rb1=15K Rb2=27K 300 200 Rb1=12K Rb2=22K 100 Rb1=12K Rb2=22K 0.0 0 2.5 3 3.5 4 4.5 Vdd(V) 5 5.5 2.5 QT1080 Idd (200m s response) µA 3 3.5 4 4.5 Vdd(V) 5 5.5 QT1080 Idd (360m s response) µA 400 300 250 200 Rb1=15K Rb2=27K 200 100 Idd(µA) Idd(µA) 300 Rb1=12K Rb2=22K Rb1=15K Rb2=27K 150 100 Rb1=12K Rb2=22K 50 0 0 2.5 3 3.5 4 4.5 Vdd(V) 5 5.5 2.5 3 3.5 4 4.5 Vdd(V) 5 5.5 Cx = 5pF, Cs = 4.7nF, Ta = 20oC, Rosc = 18K ohms; no spread spectrum circuit QT1080 Idd (norm al m ode) m A QT1080 Idd (110m s response) µA 5.0 400 300 3.0 Idd(µA) Idd(mA) 4.0 2.0 200 100 1.0 0.0 0 2.5 3 3.5 4 4.5 Vdd(V) 5 5.5 2.5 3.5 4 4.5 Vdd(V) 5 5.5 QT1080 Idd (360m s response) µA 250 125 200 100 150 75 Idd(µA) Idd(µA) QT1080 Idd (200m s response) µA 3 100 50 50 25 0 2.5 3 lQ 3.5 4 4.5 Vdd(V) 5 0 5.5 2.5 10 3 3.5 4 4.5 Vdd(V) 5 5.5 QT1080 R11.04/0206 4.7 LP Mode Typical Response Times Response Time vs Vdd - 200ms Setting 240 125 230 Actual Response Time, ms Actual Response Time, ms Response Time vs Vdd - 110ms Setting 130 120 115 110 105 100 95 90 220 210 200 190 180 170 160 2.5 3 3.5 4 4.5 5 5.5 2.5 3 3.5 Vdd 4 4.5 5 5.5 Vdd Response Time vs Vdd - 360ms Setting Actual Response Time, ms 430 410 390 370 350 330 310 290 2.5 3 3.5 4 4.5 5 5.5 Vdd lQ 11 QT1080 R11.04/0206 4.8 Mechanical - 32-QFN Package Dim e nsions In Millim e te rs Symbol Minimum Nom ina l Ma xim um A 0.70 0.90 A1 0.00 0.02 0.05 b 0.18 0.25 0.32 C 0.20 REF D 4.90 5.00 5.10 D2 3.05 3.65 E 4.90 5.00 5.10 E2 3.05 3.65 e 0.50 L 0.30 0.40 0.50 y 0.00 0.075 Note that there is no functional requirement for the large pad on the underside of this package to be soldered. If the final application requires this area to be soldered for mechanical reasons, the pad to which it is soldered to must be isolated and contained under the footprint only. 4.9 Mechanical - 48-SSOP Package A B C G J H D a F E All dimensions in millimeters Min Max lQ A 10.03 10.67 B 7.39 7.59 C 0.20 0.30 D 2.16 2.51 E 0.64 Typ 12 F 0.10 0.25 G 15.57 16.18 H 0.10 0.30 J 0.64 0.89 a 0o 8o QT1080 R11.04/0206 4.10 Part Marking 32-QFN 48-SSOP QRG Part No. QT1080 ©QRG 11 YYWWG run nr. Pin 1 Identification lQ Pin 48 QRG Revision Code DIMPLE 'YY' = Year of manufacture: 'WW' = Week of manufacture: 'G' = Green/RoHS Compliant. QT1080-IS48G © QRG 0803 R11 QProxTM <datecode> Pin 1 'run nr.' = 6 Digit Run Number 13 QT1080 R11.04/0206 lQ Copyright © 2004-2006 QRG Ltd. All rights reserved Patented and patents pending Corporate Headquarters 1 Mitchell Point Ensign Way, Hamble SO31 4RF Great Britain Tel: +44 (0)23 8056 5600 Fax: +44 (0)23 8045 3939 www.qprox.com North America 651 Holiday Drive Bldg. 5 / 300 Pittsburgh, PA 15220 USA Tel: 412-391-7367 Fax: 412-291-1015 This device covered under one or more of the following United States and corresponding international patents: 5,730,165, 6,288,707, 6,377,009, 6,452,514, 6,457,355, 6,466,036, 6,535,200. Numerous further patents are pending which may apply to this device or the applications thereof. The specifications set out in this document are subject to change without notice. All products sold and services supplied by QRG are subject to our Terms and Conditions of sale and supply of services which are available online at www.qprox.com and are supplied with every order acknowledgment. QProx, QTouch, QMatrix, QLevel, QSlide, QWheel, AKS are trademarks of QRG. QRG products are not suitable for medical (including lifesaving equipment), safety or mission critical applications or other similar purposes. Except as expressly set out in QRG's Terms and Conditions, no licenses to patents or other intellectual property of QRG (express or implied) are granted by QRG in connection with the sale of QRG products or provision of QRG services. QRG will not be liable for customer product design and customers are entirely responsible for their products and applications which incorporate QRG's products. Development Team: John Dubery, Alan Bowens, Matthew Trend