ADUC7060BCPZ32 Analog Devices Inc, ADUC7060BCPZ32 Datasheet - Page 39

ADUC7060BCPZ32

Manufacturer Part Number

ADUC7060BCPZ32

Description

DUAL 24-BIT AFE AND ARM 7 I.C

Manufacturer

Analog Devices Inc

Series

MicroConverter® ADuC7xxxr

Datasheet

1.EVAL-ADUC7061MKZ.pdf (108 pages)

Specifications of ADUC7060BCPZ32

Design Resources

4 mA-to-20 mA Loop-Powered Temperature Monitor Using ADuC7060/1 (CN0145) Low power, Long Range, ISM Wireless Measuring Node (CN0164)

Core Processor

ARM7

Core Size

16/32-Bit

Speed

10MHz

Connectivity

I²C, SPI, UART/USART

Peripherals

POR, PWM, Temp Sensor, WDT

Number Of I /o

Program Memory Size

32KB (16K x 16)

Program Memory Type

FLASH

Ram Size

4K x 8

Voltage - Supply (vcc/vdd)

2.375 V ~ 2.625 V

Data Converters

A/D 5x24b, 8x24b, D/A 1x14b

Oscillator Type

Internal

Operating Temperature

-40°C ~ 125°C

Package / Case

32-LFCSP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Eeprom Size

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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Table 39. Example Scenarios for Using Diagnostic Current Sources

ADC0DIAG[1:0] = 0

ADC0DIAG[1:0] = 1

ADC0DIAG[1:0] = 3

SINC3 FILTER

The number entered into Bits[6:0] of the ADCFLT register sets

the decimation factor of the sinc3 filter. See Table 46 and Table 47

for further details on the decimation factor values.

The range of operation of the sinc3 filter (SF) word depends on

whether the chop function is enabled. With chopping disabled,

the minimum SF word allowed is 3 and the maximum is 127,

giving an ADC throughput range of 50 Hz to 2 kHz.

For details on how to calculate the ADC sampling frequency

based on the value programmed to the SF[6:0] bits in the

ADCFLT register, refer to Table 46.

ADC CHOPPING

The ADCs on the ADuC706x implements a chopping scheme

whereby the ADC repeatedly reverses its inputs. Therefore, the

decimated digital output values from the sinc3 filter have a

positive and negative offset term associated with them. This

results in the ADC including a final summing stage that sums

and averages each value from the filter with previous filter

output values. This new value is then sent to the ADC data

MMR. This chopping scheme results in excellent dc offset and

offset drift specifications and is extremely beneficial in

applications where drift and noise rejection are required.

PROGRAMMABLE GAIN AMPLIFIER

The primary ADC incorporates an on-chip programmable gain

amplifier (PGA). The PGA can be programmed through 10

different settings giving a range of 1 to 512. The gain is

controlled by the ADC0PGA[3:0] bits in the ADC0CON MMR.

EXCITATION SOURCES

The ADuC706x contains two matched software configurable

current sources. These excitation currents are sourced from

AVDD. They are individually configurable to give a current

range of 200 μA to 1 mA. The current step sizes are 200 μA.

Description

Convert ADC0/ADC1 as normal with

diagnostic currents disabled.

Enable a 50 μA diagnostic current

source on ADC0 by setting

ADC0DIAG[1:0] = 1. Convert ADC0 and

ADC1.

Convert ADC0 in single-ended mode

with diagnostic currents disabled.

Enable a 50 μA diagnostic current

source on both ADC0 and ADC1 by

setting ADC0DIAG[1:0] = 3. Convert

ADC0 and ADC1.

Diagnostic Test

Rev. B | Page 39 of 108

Normal Result

Expected differential result

across ADC0/ADC1.

Main ADC changes by

ΔV = +50 μA × R1. For

example, ~100 mV for R1 =

2 kΩ.

Expected voltage on ADC0.

Primary ADC changes by ΔV

= 50 μA × (R1 − R2), that is,

~10 mV for 10% tolerance.

These current sources can be used to excite an external resistive

bridge or RTD sensors. The IEXCON MMR controls the

excitation current sources. Bit 6 of IEXCON must be set to

enable Excitation Current Source 0. Similarly, Bit 7 must be set

to enable Excitation Current Source 1. The output current of

each current source is controlled by the IOUT[3:0] bits of this

It is also possible to configure the excitation current sources to

output current to a single output pin, either IEXC0 or IEXC1,

by using the IEXC0_DIR and IEXC1_DIR bits of IEXCON. This

allows up to 2 mA to output current on a single excitation pin.

ADC LOW POWER MODE

The ADuC706x allows the primary and auxiliary ADCs to be

placed in low power operating mode. When configured for this

mode, the ADC throughput time is reduced, but the power

consumption of the primary ADC is reduced by a factor of

about 4; the auxiliary ADC power consumption is reduced by a

factor of roughly 3. The maximum ADC conversion rate in low

power mode is 2 kHz. The operating mode of the ADCs is

controlled by the ADCMDE register. This register configures

the part for either normal mode (default), low power mode, or

low power plus mode. Low power plus mode is the same as low

power mode except that the PGA is disabled. To place the

ADCs into low power mode, the following steps must be

completed:

•

ADCMDE[4:3]—Setting these bits enables normal mode,

low power mode, or low power plus mode.

ADCMDE[5]—Setting this bit configures the part for low

power mode.

ADCMDE[7]—Clearing this bit further reduces power

consumption by reducing the frequency of the ADC clock.

Fault Result

Short circuit.

Short circuit

between ADC0

and ADC1.

Short circuit

between R1_a

and R1_b.

ADC0 open

circuit or R1

open circuit.

R1 does not

match R2.

ADuC7060/ADuC7061

Detected

Measurement

for Fault

Primary ADC reading ≈ 0

V regardless of PGA

setting.

Primary ADC reading ≈ 0

V regardless of PGA

setting.

Primary ADC reading =

+full scale, even on the

lowest PGA setting.

Primary ADC reading >

10 mV.

ADUC7060BCPZ32 Analog Devices Inc, ADUC7060BCPZ32 Datasheet - Page 39

ADUC7060BCPZ32

Specifications of ADUC7060BCPZ32

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