QT411 Datasheet, PDF(3/12 Page) Quantum Research Group

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QT411 Datasheet, PDF (3/12 Pages) Quantum Research Group – QSLIDE TOUCH SLIDER IC

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Table 1-1 Pin Descriptions

PIN NAME TYPE DESCRIPTION

VDD

Power Positive power pin (+2.5 .. +5V)

SDO

Serial data output

/SS

Slave Select pin. This is an active low input that enables serial communications

SCLK

Serial clock input. Clock idles high

SNS3B

I/O

Sense pin (to Cs3, Rs3); connects to both slider ends, each via separate additional 8.2K ohm resistors

SNS3A

I/O

Sense pin (to Cs3)

SNS2B

I/O

Sense pin (to Cs2, Rs2); connects to 66% point (from left) of slider

SNS2A

I/O

Sense pin (to Cs2)

SNS1B

I/O

Sense pin (to Cs1, Rs1); connects to 33% point (from left) of slider

SNS1A

I/O

Sense pin (to Cs1)

SDI

Serial data input

DETECT

Active high touch detected. May be left unconnected. Note (1)

DRDY

Data ready output. Goes high to indicate it is possible to communicate with the QT411. Note (1)

VSS

Ground Negative power pin

Note (1): Pin floats ~400Âµs after wake from Sleep mode.

1.2 Free-Run Mode

If /SS stays high, the device will acquire on its own repetitively

after a timeout of about 30ms (Figure 1-2). In this mode, the

DETECT pin can be used to wake up the host when it goes

high upon touch.

In free-run mode, the device does not sleep between bursts.

In this mode the QT411 performs automatic drift

compensation at the maximum rate of one count per 1 20

acquisition burst cycles, or about one count every 7 seconds

without host intervention. It is not possible to change this

setting of drift compensation in Free-Run mode. See also

Section 3.3.3.

1.3 Sleep Mode

After an SPI transmission, the device will enter a low power

sleep state; see Figure 3-1, page 6, and Section 3.2.4, page

7 for details. This sleep state can be extended in order to

lower average power, by simply delaying the rise of /SS.

Coming out of sleep state when /SS is pulsed, the DETECT

and DRDY pins will float for ~400Âµs. It is recommended that

the DRDY pin be pulled to Vss with a resistor and DETECT

by bypassed with a capacitor to avoid false signalling if they

are being monitored during this time ; see Section 1.4.

Note: Pin /SS clamps to Vss for 250ns after coming out of

sleep state as a diagnostic pulse. To prevent a possible pin

drive conflict, /SS should either be driven by the host as an

open-drain pull-high drive (e.g. with a 100K pullup resistor), or

there should be a ~1K resistor placed in series with the /SS

pin. See Figure 1-1.

Note that activity on SCLK will also wake the QT411, which

in turn will then wait for the /SS to rise. For lowest possible

operation in Sleep mode, do not pulse on SCLK until after

/SS goes low.

1.4 DETECT Output Pin

This pin drives high when touch is detected and the chip is

reporting an angular position . This condition is also found as

bit 7 in the standard response.

This output will float for ~400Âµs during wake from Sleep mode

(see Section 1.3). It is recommended that the DETECT pin (if

it is used) be shunted to ground with a 1nF capacitor to hold

its state during the 400Âµs float interval when emerging from

Sleep.

Note that in the QT411, detection occurs when one or two of

the sensing channels becomes imbalanced with respect to

the other channel(s). A touch at one position will always

cause such an imbalance. However, a signal change that is

balanced among all 3 channels will not cause a detection. For

example, if a book is placed on top of the slider element, the

channels will all change in the same way and as a result,

detection will be suppressed. This feature is significantly

different from the way the QT401 operates.

1.5 Position Data

The position value is internally calculated and can be

accessed only when the sensor is touched (Detect pin high).

Direction convention: âLeftâ is defined as the side closest to

the connection made by SNS1, and âRightâ is defined as the

side closest to the SNS2 connection. The ends are both

connected to SNS3, each via a resistor which allows the chip

to identify left and right as separate positions. See Figure 1-1.

The use of the terms âleftâ and ârightâ should not be interpreted

to mean the device can only be used in one orientation. In

fact the strip can be oriented backwards, vertically, or at any

angle.

The position on the left end reports as 0, while the position at

the right reports as 127. The device reports 45 when touched

at the SNS1 node and 83 at SNS2. The position data is a

7-bit number (0..127) that is computed in real time and is

returned via a status command.

End stops: The QT411 defines end zones of the slider

element as saturated âend stopsâ, which consist of fixed

regions where only a reading of â0â or â127â is returned. This is

to allow robust position detection of these important locations,

so that it is easy for a user to select âfull offâ and âfull onâ. The

left slider end allocates 10% of the sliderâs length to location

â0â, and the right end similarly allocates 10% of the sliderâs

length to location â127â. Only the center 80% of the sliderâs

length will track changes in touch position in the range of

1..126.

The position data will update either with a single rapid touch

or will track if the finger is moved along the surface of the

QT411-ISSG R6.01/1005

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