SLVSC89A June 2014 – July 2014 TSC2013-Q1
PRODUCTION DATA.
MIN | MAX | UNIT | |||
---|---|---|---|---|---|
Voltage | Analog input X+, Y+, AUX to SNSGND | –0.4 | SNSVDD + 0.1 | V | |
Analog input X–, Y– to SNSGND | –0.4 | SNSVDD + 0.1 | V | ||
SNSVDD to SNSGND | –0.3 | 5 | V | ||
SNSVDD to AGND | –0.3 | 5 | V | ||
I/OVDD to AGND | –0.3 | 5 | V | ||
SNSVDD to I/OVDD | –2.4 | 0.3 | V | ||
Digital input voltage to AGND | –0.3 | I/OVDD + 0.3 | V | ||
Digital output voltage to AGND | –0.3 | I/OVDD + 0.3 | V | ||
Power dissipation | (TJmax – TA) / RθJA | ||||
Operating free-air temperature range, TA | –40 | 125 | °C | ||
Junction temperature, TJmax | 150 | °C |
MIN | MAX | UNIT | ||||
---|---|---|---|---|---|---|
Tstg | Storage temperature range | –65 | 150 | °C | ||
V(ESD) | Electrostatic discharge | Human body model (HBM), per AEC Q100-002(1) | –2000 | 2000 | V | |
Charged device model (CDM), per AEC Q100-011 | Corner pins (RSA: 1, 4, 5, 8, 9, 12, 13, and 16; PW: 1, 8, 9, and 16) |
–750 | 750 | |||
Other pins | –500 | 500 | ||||
IEC contact discharge(2) | X+, X–, Y+, Y– | –15 | 15 | kV | ||
IEC air discharge(2) | X+, X–, Y+, Y– | –25 | 25 | kV |
MIN | NOM | MAX | UNIT | |
---|---|---|---|---|
Input voltage SNSVDD/VR | 1.6 | 3.3 | 3.6 | V |
Input voltage I/OVDD | 1.2 | 3.3 | 3.6 | V |
THERMAL METRIC(1) | RSA | PW | UNIT | |
---|---|---|---|---|
16 PINS | 16 PINS | |||
RθJA | Junction-to-ambient thermal resistance | 33.7 | 100.9 | °C/W |
RθJC(top) | Junction-to-case(top) thermal resistance | 36.7 | 36.1 | °C/W |
RθJB | Junction-to-board thermal resistance | 10.5 | 45.7 | °C/W |
ψJT | Junction-to-top characterization parameter | 0.6 | 2.6 | °C/W |
ψJB | Junction-to-board characterization parameter | 10.5 | 45.1 | °C/W |
RθJC(bot) | Junction-to-case(bottom) thermal resistance | 2.5 | — | °C/W |
PARAMETER | TEST CONDITIONS | MIN | TYP | MAX | UNIT | |||
---|---|---|---|---|---|---|---|---|
AUXILIARY ANALOG INPUT | ||||||||
Input voltage | 0 | Vref | V | |||||
Input capacitance | 12 | pF | ||||||
Input leakage current | No ADC conversion | –1 | 1 | μA | ||||
Full-scale average input current | V(SNSVDD/VREF) = 1.6 V, continuous AUX, ƒ(ADC) = 2 MHz | 2 | μA | |||||
ADC | ||||||||
Resolution | Programmable: 10 or 12 bits | 12 | Bits | |||||
No missing codes | 12-bit resolution | 11 | Bits | |||||
Integral linearity | 12-bit resolution mode, ƒ(ADC) = 2 MHz | –3 | –0.5 to 0.5 | 3 | LSB(1) | |||
Differential linearity | 12-bit resolution mode, fADC = 2MHz | –2 | –0.5 to 0.5 | 4 | LSB | |||
Offset error | V(SNSVDD/VREF) = 1.6 V, 12-bit mode, ƒ(ADC) = 2 MHz, filter off | 0.2 | LSB | |||||
Gain error | V(SNSVDD/VREF) = 1.6 V, 12-bit mode, ƒ(ADC) = 2 MHz, filter off | 2 | LSB | |||||
Data format | Straight binary | |||||||
REFERENCE INPUT | ||||||||
Vref range | 1.6 | V(SNSVDD/VREF) | V | |||||
SNSVDD/VREF input-current drain | Continuous AUX mode, V(SNSVDD/VREF) = 1.6 V, ƒ(ADC) = 2 MHz | 5 | μA | |||||
Input impedance | No ADC conversion | > 100 | MΩ | |||||
TOUCH SENSORS | ||||||||
X+ 50-kΩ pullup resistor, R(IRQ) | 52 | kΩ | ||||||
Switch on-resistance | Y+, X+ | TA = 25°C, V(SNSVDD/VREF) = 1.6 V | 7 | Ω | ||||
Y–, X– | TA = 25°C, V(SNSVDD/VREF) = 1.6 V | 5 | Ω | |||||
Switch drivers drive current | 100-ms duration | 50 | mA | |||||
INTERNAL OSCILLATOR | ||||||||
ƒ(OSC) | Clock frequency | V(SNSVDD/VREF) = 1.6 V, TA = 25°C | 3.3 | 3.7 | 4.3 | MHz | ||
V(SNSVDD/VREF) = 3 V, TA = 25°C | 3.8 | MHz | ||||||
Frequency drift | V(SNSVDD/VREF) = 1.6 V | –0.008 | %/°C | |||||
V(SNSVDD/VREF) = 3 V | –0.021 | %/°C | ||||||
DIGITAL INPUT/OUTPUT | ||||||||
Logic family | CMOS | |||||||
VIH | Input-voltage logic-level high | 1.2 V ≤ V(I/OVDD) < 3 V | 0.7 × V(I/OVDD) | 3.6 | V | |||
VIL | Input-voltage logic-level low | 1.2 V ≤ V(I/OVDD) < 3 V | –0.3 | 0.2 × V(I/OVDD) | V | |||
IIL, IIH | Input-current logic-level low and high | –1 | 1 | μA | ||||
CI | Input-capacitance logic level | 10 | pF | |||||
VOH | Output-voltage logic-level high | IOH = 100 μA | V(I/OVDD) – 0.2 | V(I/OVDD) | V | |||
VOL | Output-voltage logic-level low | IOL = –3.2 mA | 0 | 0.2 | V | |||
Ilkg | Leakage-current logic level | SDA | –1 | 1 | μA | |||
CO | Output-capacitance logic level | SDA | 10 | pF | ||||
POWER-SUPPLY REQUIREMENTS | ||||||||
Power-supply voltage | ||||||||
SNSVDD | 1.6 | 3 | V | |||||
I/OVDD(2) | 1.2 | V(SNSVDD/VREF) | V | |||||
Quiescent supply current(3)(4) |
TA = 25°C, filter off, M = W = 1, C[3:0] = (1, 0, 0, 0), RM = 1, CL[1:0] = (0, 1), cont AUX mode, ƒ(ADC) = 2 MHz, without reading data register | V(SNSVDD/VREF) = V(I/OVDD) = 1.6 V | 420 | 570 | μA | |||
TA = 25°C, filter on, M = 15, W = 7, PSM = 1, C[3:0] = (0, 0, 0, 0), RM = 1, CL[1:0] = (0, 1), BTD[2:0] = (1, 0, 1), 50 SSPS, MAVEX = MAVEY = MAVEZ = 1, ƒ(ADC) = 2 MHz, sensor drivers supply included(5) | V(SNSVDD/VREF) = V(I/OVDD) = 1.6 V | 200 | μA | |||||
V(SNSVDD/VREF) = V(I/OVDD) = 3 V | 400 | μA | ||||||
TA = 25°C, filter off, M = W = 1, PSM = 1, C[3:0] = (0, 0, 0, 0), RM = 1, CL[1:0] = (0, 1), BTD[2:0] = (1, 0, 1), 50 SSPS, MAVEX = MAVEY = MAVEZ = 1, ƒ(ADC) = 2 MHz, sensor drivers supply included(5) | V(SNSVDD/VREF) = V(I/OVDD) = 1.6 V | 180 | μA | |||||
V(SNSVDD/VREF) = V(I/OVDD) = 3 V | 370 | μA | ||||||
TA = 25°C, filter off, M = W = 1, C[3:0] = (0, 1, 0, 1), RM = 1, CL[1:0] = (0, 1), non-cont AUX mode, ƒ(ADC) = 2 MHz, high-speed mode | V(SNSVDD/VREF) = V(I/OVDD) = 1.6 V, approximately 28 kSPS effective rate | 190 | μA | |||||
V(SNSVDD/VREF) = V(I/OVDD) = 3 V, approximately 28.4 kSPS effective rate | 370 | μA | ||||||
TA = 25°C, filter on, M = 7, W = 3, C[3:0] = (0, 1, 0, 1), RM = 1, CL[1:0] = (0, 1), MAVEAUX = 1, non-cont AUX mode, ƒ(ADC) = 2 MHz, high-speed mode, full speed | V(SNSVDD/VREF) = V(I/OVDD) = 1.6 V, approximately 10.5 kSPS effective rate | 355 | μA | |||||
V(SNSVDD/VREF) = V(I/OVDD) = 3 V, approximately 10.9 kSPS effective rate | 655 | μA | ||||||
TA = 25°C, filter on, M = 7, W = 3, C[3:0] = (0, 1, 0, 1), RM = 1, CL[1:0] = (0, 1), MAVEAUX = 1, non-cont AUX mode, ƒ(ADC) = 2 MHz, high-speed mode, reduced speed (8.2-kSPS equivalent rate) | V(SNSVDD/VREF) = V(I/OVDD) = 1.6 V, approximately 1.17 kSPS effective rate | 36.2 | μA | |||||
V(SNSVDD/VREF) = V(I/OVDD) = 3 V, approximately 1.17 kSPS effective rate | 64.9 | μA | ||||||
Power-down supply current | TA = 25°C, not addressed, SCL = SDA = 1, RESET = 1, PINTDAV = 1, V(SNSVDD/VREF) = I/OVDD = Vref = 1.6 V |
0.04 | 0.8 | μA | ||||
Digital power-down supply current | TA = 25°C, not addressed, SCL = SDA = 1, RESET = 1, PINTDAV = 1, V(SNSVDD/VREF) = V(I/OVDD) = Vref = 1.6 V |
0.04 | 0.8 | μA |
MIN | MAX | UNIT | |||
---|---|---|---|---|---|
t(WL_RESET) | Reset low time(1) | See Figure 1 and Figure 37 | 10 | μs | |
ƒ(SCL) | SCL clock frequency | 100 | kHz | ||
t(BUF) | Bus free time between a STOP and START condition | See Figure 1 | 4.7 | μs | |
th(STA) | Hold time for (repeated) START condition | 4 | μs | ||
t(LOW) | Low period of SCL clock | 4.7 | μs | ||
t(HIGH) | High period of the SCL clock | 4 | μs | ||
tsu(STA) | Setup time for a repeated START condition | 4.7 | μs | ||
th(DAT) | Data hold time | 0 | 3.45 | μs | |
tsu(DAT) | Data setup time | 250 | ns | ||
tr | Rise time of both SDA and SCL signals | C(b) = total bus capacitance See Figure 1 |
1000 | ns | |
tf | Fall time of both SDA and SCL signals | 300 | ns | ||
tsu(STO) | Setup time for STOP condition | See Figure 1 | 4 | μs | |
C(b) | Capacitive load for each bus line | C(b) = total capacitance of one bus line in pF | 400 | pF | |
td(SP) | Pulse duration of spikes that must be suppressed by the input filter | N/A | N/A | ns |
MIN | MAX | UNIT | |||
---|---|---|---|---|---|
t(WL_RESET) | Reset low time(2) | See Figure 1 and Figure 37 | 10 | μs | |
ƒ(SCL) | SCL clock frequency | 400 | kHz | ||
t(BUF) | Bus free time between a STOP and START condition | See Figure 1 | 1.3 | μs | |
th(STA) | Hold time for (repeated) START condition | 0.6 | μs | ||
t(LOW) | Low period of SCL clock | 1.3 | μs | ||
t(HIGH) | High period of the SCL clock | 0.6 | μs | ||
tsu(STA) | Setup time for a repeated START condition | 0.6 | μs | ||
th(DAT) | Data hold time | 0 | 0.9 | μs | |
tsu(DAT) | Data setup time | 100 | ns | ||
tr | Rise time of both SDA and SCL signals | C(b) = total bus capacitance See Figure 1 |
20 + 0.1 × C(b) | 300 | ns |
tf | Fall time of both SDA and SCL signals(1) | 20 + 0.1 × C(b) | 300 | ns | |
tsu(STO) | Setup time for STOP condition | See Figure 1 | 0.6 | μs | |
C(b) | Capacitive load for each bus line | C(b) = total capacitance of one bus line in pF | 400 | pF | |
td(SP) | Pulse duration of spikes that must be suppressed by the input filter | 0 | 50 | ns |
MIN | MAX | UNIT | |||
---|---|---|---|---|---|
t(WL_RESET) | Reset low time(2) | See Figure 2 and Figure 37 | 10 | μs | |
ƒ(SCL) | SCL clock frequency | 1.7 | MHz | ||
th(STA) | Hold time of (repeated) START condition | See Figure 2 | 160 | ns | |
t(LOW) | Low period of SCL clock | 320 | ns | ||
t(HIGH) | High period of the SCL clock | 120 | ns | ||
tsu(STA) | Setup time for a repeated START condition | 160 | ns | ||
th(DAT) | Data hold time | 0 | 150 | ns | |
tsu(DAT) | Data setup time | 10 | ns | ||
tr(CL) | Rise time of SCL signal | C(b) = total bus capacitance(1)
Figure 2 |
20 | 80 | ns |
tr(DA) | Rise time of SDA signal | 20 | 160 | ns | |
tf(CL) | Fall time of SCL signal | 20 | 80 | ns | |
tf(DA) | Fall time of SDA signal | 1 | 160 | ns | |
tr(CL1) | Rise time of SCL signal after a repeated START condition and after an acknowledge bit | 20 | 160 | ns | |
tsu(STO) | Setup time for STOP condition | See Figure 2 | 160 | ns | |
C(b) | Capacitive load for each bus line | C(b) = total capacitance of one bus line in pF | 400 | pF | |
td(SP) | Pulse duration of spikes that must be suppressed by the input filter | 0 | 10 | ns |
MIN | MAX | UNIT | |||
---|---|---|---|---|---|
t(WL_RESET) | Reset low time(3) | See Figure 2 and Figure 37 | 10 | μs | |
ƒ(SCL) | SCL clock frequency | 3.4 | MHz | ||
th(STA) | Hold time for (repeated) START condition | See Figure 2 | 160 | ns | |
t(LOW) | Low period of SCL clock | 160 | ns | ||
t(HIGH) | High period of the SCL clock | 60 | ns | ||
tsu(STA) | Setup time for a repeated START condition | 160 | ns | ||
th(DAT) | Data hold time | 0 | 70 | ns | |
tsu(DAT) | Data setup time | 10 | ns | ||
tr(CL) | Rise time of SCL signal | C(b) = total bus capacitance(2)
See Figure 2 |
10 | 40 | ns |
tr(DA) | Rise time of SDA signal | 10 | 80 | ns | |
tf(CL) | Fall time of SCL signal | 10 | 40 | ns | |
tf(DA) | Fall time of SDA signal | 1 | 80 | ns | |
tr(CL1) | Rise time of SCL signal after a repeated START condition and after an acknowledge bit | 10 | 80 | ns | |
tsu(STO) | Setup time for STOP condition | See Figure 2 | 160 | ns | |
C(b) | Capacitive load for each bus line | C(b) = total capacitance of one bus line in pF | 100 | pF | |
td(SP) | Pulse duration of spikes that must be suppressed by the input filter | 0 | 10 | ns |
M = 1 | W = 1 (See Table 1) | ƒ(SAMPLE) = 28 kHz |
AUX non-continuous mode |
t(PVS), t(PRE), t(SNS) = default values | ||
TSC-initiated mode scan X, Y, and Z at 50SSPS | ||
Touch sensor modeled by: 2 kΩ for X-plane and Y-plane and 1 kΩ for Z (touch resistance, See Figure 14) |
TA = 25°C | ||
IOVDD = SNSVDD/VREF | ƒ(SAMPLE) = 28 kHz | |
IOVDD = SNSVDD/VREF | AUX continuous mode | |||
TA = 25°C |
TA = 25° C | ||
I/OVDD = SNSVDD/VREF | ||
IOVDD = SNSVDD/VREF | AUX continuous mode | |