aduc7033bstz-8l-rl Analog Devices, Inc., aduc7033bstz-8l-rl Datasheet - Page 63

aduc7033bstz-8l-rl

Manufacturer Part Number

aduc7033bstz-8l-rl

Description

Integrated Precision Battery Sensor For Automotive

Manufacturer

Analog Devices, Inc.

Datasheet

1.ADUC7033BSTZ-8L-RL.pdf (136 pages)

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Self-Calibration

In self (offset or gain) calibration, the ADC generates its

calibration coefficient based on an internally generated 0 V in

the case of self-offset calibration, and full-scale voltage in the

case of self-gain calibration. It should be emphasized that ADC

self-calibrations correct for offset and gain errors within the

ADC. Self-calibrations cannot compensate for other external

errors in the system, for example, shunt resistor tolerance/drift,

external offset voltages, and so on.

Note that in self-calibration mode, ADC0GN must first contain

the values for PGA = 1, before a calibration scheme is started.

System Calibration

In system (offset or gain) calibration, the ADC generates

its calibration coefficient based on an externally generated

zero-scale voltage (in the case of system offset calibration) and

full-scale voltage (in the case of system gain calibration), which

are applied to the external ADC input for the duration of the

calibration cycle.

The duration of an offset calibration is a single conversion cycle

(3/f

ADC to idle mode. A gain calibration is a two-stage process

and, therefore, takes twice as long as an offset calibration cycle.

When a calibration cycle is initiated, any ongoing ADC conver-

sion is immediately halted, the calibration is automatically carried

out at an ADC update rate programmed into ADCFLT, and the

ADC is always returned to idle after any calibration cycle. It is

strongly recommended that ADC calibration is initiated at as

low an ADC update rate as possible (high SF value in ADCFLT)

to minimize the impact of ADC noise during calibration.

Using the Offset and Gain Calibration

If the Chop Enable Bit ADCFLT[15] is enabled, then internal

ADC offset errors are minimized and an offset calibration may

not be required. If chopping is disabled however, an initial offset

calibration is required and may need to be repeated, particularly

after a large change in temperature.

A gain calibration, particularly in the context of the I-ADC

(with internal PGA), may need to be carried out at all relevant

system gain ranges depending on system accuracy requirements.

If it is not possible to apply an external full-scale current on all

gain ranges, then it is possible to apply a lower current and scale

the result produced by the calibration. For example, apply a 50%

current and then divide the ADC0GN value produced-by-two

and write this value back into ADC0GN. Note that there is a

lower limit to the input signal that can be applied for a system

calibration because ADC0GN is only a 16-bit register. The input

span (difference between the system zero-scale value and system

full-scale value) should be greater than 40% of the nominal full-

scale-input range, that is, >40% of V

The on-chip Flash/EE memory can be used to store multiple

calibration coefficients. These can be copied by user code

ADC

with chop off, 2/f

ADC

with chop on) before returning the

REF

/gain.

Rev. 0 | Page 63 of 136

directly into the relevant calibration registers, as appropriate,

based on the system configuration. In general, the simplest way

to use the calibration registers is to let the ADC calculate the

values required as part of the ADC automatic calibration modes.

A factory, or end-of-line calibration, for the I-ADC is a two-

step procedure.

1. Apply 0 A current. Configure the ADC in the required PGA

setting, and so on, and write to ADCMDE[2:0] to perform a

system zero-scale calibration. This writes a new offset

calibration value into ADC0OF.

2. Apply a full-scale current for the selected PGA setting. Write

to ADCMDE to perform a system full-scale calibration. This

writes a new gain calibration value into ADC0GN.

Understanding the Offset and Gain Calibration Registers

The output of the average block in the ADC signal flow

(described previously from the ADC Sinc3 Digital Filter

Response section to the Using the Offset and Gain Calibration

section) can be considered a fractional number with a span for

a ±full-scale input of approximately ±0.75. The span is less than

±1.0 because there is attenuation in the modulator to accommo-

date some overrange capacity on the input signal. The exact

value of the attenuation varies slightly from part to part,

because of manufacturing tolerances.

The offset coefficient is read from the ADC0OF calibration

range of this number, in terms of the signal chain, is effectively

±1.0. Therefore, 1 LSB of the ADC0OF register is not the same

as 1 LSB of ADC0DAT.

A positive value of ADC0OF indicates that when offset is

subtracted from the output of the filter, a negative value is added.

The nominal value of this register is 0x0000, indicating zero

offset is to be removed. The actual offset of the ADC can vary

slightly from part to part and at different PGA gains. The offset

within the ADC is minimized if the chopping mode is active

(ADCFLT[15] = 1).

The gain coefficient is a unitless scaling factor. The 16-bit value

in this register is divided by 16,384 and then multiplied by the

offset corrected value. The nominal value of this register equals

0x5555, corresponding to a multiplication factor of 1.3333. This

scales the nominal ±0.75 signal to produce a full-scale output

signal of ±1.0, which is checked for overflow/underflow and

converted to twos complement or unipolar mode as appropriate

before being output to the data register.

The actual gain, and the required scaling coefficient for zero

gain error, varies slightly from part to part, at different PGA

settings, and in normal/low power mode. The value down-

loaded into ADC0GN at power-on-reset represents the scaling

factor for a PGA gain = 1. There is some level of gain error if

this value is used at different PGA settings. User code can

ADuC7033

aduc7033bstz-8l-rl Analog Devices, Inc., aduc7033bstz-8l-rl Datasheet - Page 63

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