qt511 Quantum Research Group, qt511 Datasheet - Page 5

qt511

Manufacturer Part Number

qt511

Description

Qwheel? Touch Slider Ic

Manufacturer

Quantum Research Group

Datasheet

1.QT511.pdf (12 pages)

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2.2 Cs Sample Capacitors

Cs1, Cs2 and Cs3 are the charge sensing sample capacitors;

normally they are identical in nominal value. They should be

of type X7R dielectric.

The optimal Cs values depend on the thickness of the panel

and its dielectric constant. Lower coupling to a finger caused

by a low dielectric constant and/or thicker panel will cause the

position result to become granular and more subject to

position errors. The ideal panel is made of thin glass. The

worst panel is thick plastic. Granularity due to poor coupling

can be compensated for by the use of larger values of sample

capacitors.

A table of suggested values for no missing position values is

shown in Table 1-2. Values of Cs smaller than those shown in

the table can cause skipping of position codes. Code skipping

may be acceptable in many applications where fine position

data is not required. Smaller Cs capacitors have the

advantage of requiring shorter acquisition bursts and hence

lower power drain.

Larger values of Cs improve granularity at the expense of

longer burst lengths and hence more average power.

Cs1, Cs2 and Cs3 should be X7R type, matched to within

10% of each other (ie, 5% tolerance) for best accuracy. The

PCB reference layout (Figure 1-3) is highly recommended. If

the Cs capacitors are poorly matched, the wheel accuracy will

be affected and there could also be missing codes.

2.3 Rs Resistors

Rs1, Rs2, and Rs3 are low value (typically 4.7K) resistors

used to suppress the effects of ESD and assist with EMC

compliance. They are optional in many cases.

2.4 Power Supply

The usual power supply considerations with QT parts applies

also to the QT511. The power should be very clean and come

from a separate regulator if possible. This is particularly

critical with the QT511 which reports continuous position as

opposed to just an on/off output.

A ceramic 0.1µF bypass capacitor should be placed very

close to the power pins of the IC.

Regulator stability: Most low power LDO regulators have

very poor transient stability, especially when the load

transitions from zero current to full operating current in a few

microseconds. With the QT511 this happens when the device

comes out of sleep mode. The regulator output can suffer

from hundreds of microseconds of instability at this time,

which will have a negative effect on acquisition accuracy.

To assist with this problem, the QT511 waits 500µs after the

400µs taken to come out of sleep mode before acquiring to

allow power to fully stabilize. This delay is not present before

an acquisition burst if there is no preceding sleep state.

Use an oscilloscope to verify that Vdd has stabilized to within

5mV or better of final settled voltage before a burst begins.

The QT511 has specially enhanced power supply rejection

built in. This means that it is often possible to share the

regulator with other circuits. However, it is always advised to

be sure that Vdd is free from spikes and transients, and is

filtered sufficiently to prevent detection problems.

During development it is wise to first design a regulator onto

the PCB just for (and next to) the QT511, but allow for it to be

‘jumpered out’. If in development it is clear that there are no

problems with false detection or ‘angle noise’ even without a

regulator just for the QT511, then the regulator can be safely

omitted.

2.5 PCB Layout and Mounting

The E510 PCB layout (Figure 1-3) should be followed if

possible. This is a 1-sided board; the blank side is simply

adhered to the inside of a 2mm thick (or less) control panel.

Thicker panels can be tolerated with additional position error

due to capacitive ‘hand shadow’ effects and will also have

poorer EMC performance.

This layout uses 18 copper pads connected with intervening

series resistors in a circle. The finger interpolates between

the copper pads (if the pads are narrow enough) to make a

smooth, 0..127 step output with no apparent stair-casing. The

lateral dimension along the centre of each electrode should

be no wider than the expected smallest diameter of finger

touch, to prevent stair-casing of the position response (if that

matters).

Other geometries are possible, for example triangles and

squares. The wheel can be made in various diameters up to

at least 80mm. The electrode width should be about 12mm

wide or more, as a rule.

The SMT components should be oriented perpendicular to

the direction of bending so that they do not fracture when the

PCB is flexed during bonding to the panel.

Additional ground area or a ground plane on the PCB will

compromise signal strength and is to be avoided. A single

sided PCB can be made of FR-2 or CEM-1 for low cost.

‘Handshadow’ effects: With thicker and wider panels an

effect known as ‘handshadow’ can become noticeable. If the

capacitive coupling from finger to electrode element is weak,

for example due to a narrow electrode width or a thick, low

dielectric constant panel, the remaining portion of the human

hand can contribute a significant portion of the total

detectable capacitive load. This will induce an offset error,

which will depend on the proximity and orientation of the hand

to the remainder of the element. Thinner panels and those

with a smaller diameter will reduce this effect since the finger

contact surface will strongly domina te the total signal, and the

remaining handshadow capacitance will not contribute

significantly to create an error offset.

PCB Cleanliness: All capacitive sensors should be treated

as highly sensitive circuits which can be influenced by stray

conductive leakage paths. QT devices have a basic

resolution in the femtofarad range; in this region, there is no

such thing as ‘no clean flux’. Flux absorbs moisture and

becomes conductive between solder joints, causing signal

drift and resultant false detections or temporary loss of

sensitivity. Conformal coatings will trap in existing amounts of

moisture which will then become highly temperature

sensitive.

The designer should specify ultrasonic cleaning as part of the

manufacturing process, and in extreme cases, the use of

conformal coatings after cleaning.

QT511-ISSG R6.01/1005

qt511 Quantum Research Group, qt511 Datasheet - Page 5

qt511

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