ZSC31010CIG1-R Datasheet ZSC31010CEG1-R, ZSC31010CIG1-R, ZSC31010CIG1-T | P13-P15

ZSC31010 Datasheet

January 20, 2016

)

TcoTB

_OffsetRaw

_BR()

TcgT

B_Gain

ZB ∗∆

++∗

∗∆+

)ZBSOT25.1(ZBBR ∗+=

2.3. Digital Signal Processor

A digital signal processor (DSP) is used for processing the converted bridge data as well as for performing

temperature correction and for computing the temperature value for output on the digital channel.

The DSP reads correction coefficients from the EEPROM and can correct for

• Bridge Offset

• Bridge Gain

• Variation of Bridge Offset over Temperature (Tco)

• Variation of Bridge Gain over Temperature (Tcg)

• A Single Second Order Effect (SOT - Second Order Term)

The EEPROM contains a single SOT that can be applied to correct one and only one of the following:

• 2

order behavior of bridge measurement

• 2

order behavior of Tco

• 2

order behavior of Tcg

(For more details, see section 3.6.1.)

If the SOT applies to correcting the bridge reading, then the correction formula for the bridge reading is

represented as a two step process as follows:

(1)

(2) `

Where:

BR = Corrected Bridge reading that is fed as digital or analog output on Sig™ pin

ZB = Intermediate result in the calculations

BR_Raw = Raw Bridge reading from ADC

T_Raw = Raw Temperature reading converted from PTAT signal

Gain_B = Bridge gain term

Offset_B = Bridge offset term

Tcg = Temperature coefficient gain

Tco = Temperature coefficient offset

∆T = (T_Raw - T

SETL

)

T_Raw = Raw Temperature reading converted from PTAT signal

SETL

= Raw PTAT reference value (See Technical Note—ZSC31010, ZSC31015, and ZSSC3015

Calibration Sequence, DLL, and EXE for details.)

SOT = Second Order Term

Note: See section 3.6.2.7 for limitations when SOT applies to the bridge reading.

ZSC31010 Datasheet

January 20, 2016

)]TcoTSOT(TB_OffsetRaw_BR[)TcgT1(B_GainBR

+∆∗∆++∗∗∆+=

]TcoTB_OffsetRaw_BR[)]TcgTSOT(T1[B_GainBR

∗∆++∗+∆∗∆+=

)T_OffsetRaw_T(T_GainT +=

If the SOT applies to correcting the 2

order behavior of Tco, then the formula for bridge correction is as follows:

(3)

Note: See section 3.6.2.7 for limitations when SOT applies to Tco.

If the SOT applies to correcting the 2

order behavior of Tcg, then the formula for bridge correction is as follows:

(4)

The bandgap reference gives a very linear PTAT signal, so temperature correction can always simply be

accomplished with a linear gain and offset term.

Corrected Temp Reading:

(5)

Where:

T_Raw = Raw Temperature reading converted from PTAT signal

Offset_T = Temperature sensor offset coefficient

Gain_T = Temperature gain coefficient

2.3.1. EEPROM

The EEPROM contains the calibration coefficients for gain and offset, etc., and the configuration bits, such as

output mode, update rate, etc. When programming the EEPROM, an internal charge-pump voltage is used, so a

high voltage supply is not needed. The EEPROM is implemented as a shift register. During an EEPROM read, the

contents are shifted 8 bits before each transmission of one byte occurs.

The charge-pump is internally regulated to 12.5 V, and the programming time is typically 6 ms.

Note: EEPROM writing can only be performed at temperatures lower than 85°C.

2.3.2. One-Wire Interface—ZACwire™

The IC communicates via a One-Wire Serial Interface (OWI, ZACwire™). There are different commands available

for the following:

• Reading the conversion result of the ADC (Get_BR_Raw, Get_T_Raw)

• Calibration commands

• Reading from the EEPROM (dump of entire contents)

• Writing to the EEPROM (trim setting, configuration, and coefficients)

ZSC31010 Datasheet

January 20, 2016

Settling Time

64 ms

AD Conversion

768 ms

Calculation

160

DAC output

occurs here

DAC output

next update

Settling Time

64 ms

AD Conversion

768 ms

Calculation

160 ms

2.4. Output Stage

2.4.1. Digital to Analog Converter (Output DAC)

An 11-bit DAC, based on sub-ranging resistor strings, is used for the digital-to-analog output conversion in the

analog ratiometric and absolute analog voltage modes. Selection during calibration configures the system to

operate in either of these modes. The design allows for excellent testability as well as low power consumption.

Figure 2.2 shows the data timing of the DAC output with the 1 kHz update rate setting.

Figure 2.2 DAC Output Timing for Highest Update Rate

2.4.2. Output Buffer

A rail-to-rail operational amplifier (OpAmp) configured as a unity gain buffer can drive resistive loads (whether

pull-up or pull-down) as low as 2.5 kΩ and capacitances up to 15 nF. To limit the error due to amplifier offset

voltage, an error compensation circuit is included which tracks and reduces the offset voltage to < 1 mV.

2.4.3. Voltage Reference Block

A linear regulator control circuit is included in the Voltage Reference Block to interface with an external JFET

to allow operation in systems where the supply voltage exceeds 5.5 V. This circuit can also be used for over-

voltage protection. The regulator set point has a coarse adjustment via an EEPROM bit (see section 2.3.1), which

can adjust the set point around 5.0 V or 5.5 V. In addition, the 1 V trim setting (see below) can also act as a fine

adjustment for the regulation set point.

Note: If using the external JFET for over-voltage protection purposes (i.e., 5 V at JFET drain and expecting 5 V

at JFET source), there will be a voltage drop across the JFET; therefore ratiometricity will be compromised

somewhat depending on the rds(on) of the chosen JFET. A Vishay J107 is the best choice, because it has only

an 8 mV drop worst case. If using as regulation instead of over-voltage, an MMBF4392 also works well.

The Voltage Reference Block uses the absolute reference voltage provided by the Bandgap to produce two

regulated on-chip voltage references. A 1 V reference is used for the output DAC high reference, when the part is

configured for 0 to 1 V analog output. For this reason, the 1 V reference must be very accurate and includes trim,

such that its value can be trimmed within +/-3 mV of 1.0 V. The 1 V reference is also used as the on-chip

reference for the JFET regulator block, so the regulation set point of the JFET regulator can be fine-tuned, using

the 1 V trim. The 5 V reference can be trimmed within +/-15 mV. Table 2.1 shows the order of trim codes with

0111

for the lowest reference voltage, and 1000

for the highest reference voltage.

P1-P3 P4-P6 P7-P9 P10-P12 P13-P15 P16-P18 P19-P21 P22-P24 P25-P27 P28-P30 P31-P33 P34-P36 P37-P39 P40-P42 P43-P43

ZSC31010CIG1-R

Mfr. #:

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Sensor Interface Sensor Signal Conditoner

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ZSC31010CIG1-R

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