QT310-D ETC, QT310-D Datasheet - Page 12

QT310-D

Manufacturer Part Number

QT310-D

Description

PROGRAMMABLE CAPACITANCE SENSOR IC

Manufacturer

ETC

Datasheet

1.QT310-D.pdf (20 pages)

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If the power supply is shared with another electronic system,

care should be taken to assure that the supply is free of

spikes, sags, and surges. In BG1 mode the QT310 will track

slow changes in Vdd if drift compensation is enabled, but it

can be adversely affected by rapid voltage steps and spikes

at the millivolt level.

If desired, the supply can be regulated using a conventional

low current regulator, for example CMOS LDO regulators with

low quiescent currents, or standard 78Lxx-series 3-terminal

regulators.

For proper operation a 100nF (0.1uF) ceramic bypass

capacitor must be used between Vdd and Vss; the bypass

cap should be placed very close to the Vdd and Vss pins.

3.3 PCB LAYOUT

3.3.1 G

The use of ground planes around the device is encouraged

for noise reasons, but ground should not be coupled too close

to the sense pins in order to reduce Cx load. Likewise, the

traces leading from the sense pins to the electrode should not

be placed directly over a ground plane; rather, the ground

plane should be relieved by at least 3 times the width of the

sense traces directly under it, with periodic thin bridges over

the gap to provide ground continuity.

3.3.2 C

If a cloning connector is used, place this close to the QT310.

Placing the cloning connector far from the QT310 will increase

the load capacitance Cx of the sensor line SNS1 and

decrease sensitivity. Long distances on these lines can also

make the cloning process more susceptible to communication

errors from ringing and interference.

If the SYNC_I input is used, a 10K ohm resistor should be

used to avoid conflicts with the cloning process (Figure 4-1).

Cloning can be designed for production by using pads (SMT

or through-hole) on the solder side which are connected to a

fixture via spring loaded ATE-style ‘pogo-pins’. This eliminates

the need for an actual connector to save cost.

Important Note: Since SCK is shared on the SNS1 pin, it is

possible that stray external fields can cause these devices to

enter into Clone mode accidentally. If long wiring or large

electrodes are used that could pick up interference, install a

470K resistor from SNS1 to ground to suppress pickup. If the

device enters clone mode accidentally, it may be necessary to

cycle power to recover the device.

3.4 ESD ISSUES

In cases where the electrode is placed behind a dielectric

panel, the device will usually be well protected from static

discharge. However, even with a plastic or glass panel,

transients can still flow into the electrode via induction, or in

extreme cases, via dielectric breakdown. Porous materials

may allow a spark to tunnel right through the material; partially

conducting materials like 'pink poly' static dissipative plastics

will conduct the ESD right to the electrode. Panel seams can

permit discharges through edges or cracks.

Testing is required to reveal any problems. The QT310 has

internal diode protection which can absorb and protect the

device from most induced discharges, up to 20mA; the

usefulness of the internal clamping will depend on the

LONE

ROUND

ORT

LANES

ONNECTO

dielectric properties, panel thickness, and rise time of the

ESD transients.

ESD protection can be enhanced with an added resistor RE1

(Figure 3-1). As the transfer time is ~833ns, the circuit can

tolerate values of RE1 which result in an RC timeconstant of

1/6th this amount or about 140ns. The ‘C’ of the RC is the Cx

load. Thus, for Cx= 20pF, the maximum of RE1 should be

6.8K ohms. Larger amounts of RE1 or Cx may result in

noticeably reduced gain.

3.5 EMC ISSUES

Electromagnetic and electrostatic susceptibility are often a

problem with capacitive sensors. QT310 behavior under these

conditions can be improved by adding RE1 (Figure 3-1),

exactly as for ESD protection. The resistor should be placed

next to the chip.

This works because the inbound RC network formed by RE1

and Cs has a very low cut-off frequency which can be

computed by the formula:

If R = 6.8K and Cs = 10nF, then Fc = 2,340 Hz.

This leads to very strong suppression of external field effects.

Nevertheless, it is always wise to reduce lead lengths by

placing the QT310 as close to the electrode as possible.

/ SYNC_O

/ SYNC_I

/ CAL

Figure 3-1 ESD/EMC protection resistors

Fc =

Figure 4-1 Clone interface wiring

RE3

RE4

RE5

2✜ R Cs

CAL

SYNC_O

SYNC_I

/ C AL

/ S YNC_O

SDO

VDD

VSS

SNS 2

SNS1

SNS2

SCK

OUT

SDI

100nF

QT310/R1.03 21.09.03

100 nF

RE1

RE2

OUT

SENSOR

QT310-D ETC, QT310-D Datasheet - Page 12

QT310-D

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