MAX1040 Datasheet, PDF(18/44 Page) Maxim Integrated Products – 10-Bit, Multichannel ADCs/DACs with FIFO, Temperature Sensing, and GPIO Ports

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MAX1040 Datasheet, PDF (18/44 Pages) Maxim Integrated Products – 10-Bit, Multichannel ADCs/DACs with FIFO, Temperature Sensing, and GPIO Ports

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10-Bit, Multichannel ADCs/DACs with FIFO,

Temperature Sensing, and GPIO Ports

Detailed Description

The MAX1040âMAX1043/MAX1046âMAX1049 integrate

a multichannel 10-bit ADC and a quad 10-bit DAC in a

single IC. These devices also include a temperature

sensor and configurable GPIOs with a 25MHz SPI-

/QSPI-/MICROWIRE-compatible serial interface. The

ADC is available in a 4 or an 8 input-channel version.

The four DAC outputs settle within 2.0Âµs, and the ADC

has a 300ksps conversion rate.

All devices include an internal reference (2.5V or

4.096V) providing a well-regulated, low-noise reference

for both the ADC and DAC. Programmable reference

modes for the ADC and DAC allow the use of an inter-

nal reference, an external reference, or a combination

of both. Features such as an internal Â±1Â°C accurate

temperature sensor, FIFO, scan modes, programmable

internal or external clock modes, data averaging, and

AutoShutdown allow users to minimize both power con-

sumption and processor requirements. The low glitch

energy (4nVâ¢s) and low digital feedthrough (0.5nVâ¢s) of

the integrated quad DACs make these devices ideal for

digital control of fast-response closed-loop systems.

The devices are guaranteed to operate with a supply

voltage from +2.7V to +3.6V (MAX1041/MAX1043/

MAX1047/MAX1049) and from +4.5V to +5.5V

(MAX1040/MAX1042/MAX1046/MAX1048). These

devices consume 2.5mA at 300ksps throughput, only

0.22ÂµA at 1ksps throughput, and under 0.2ÂµA in the

shutdown mode. The MAX1042/MAX1043/MAX1048/

MAX1049 offer four GPIOs that can be configured as

inputs or outputs.

Figure 1 shows the MAX1042/MAX1043 functional dia-

gram. The MAX1042/MAX1043/MAX1048/MAX1049 only

include the GPIO A0, A1, GPIO C0, C1 blocks. The

MAX1040/MAX1041/MAX1046/MAX1047 exclude the

GPIOs. The output-conditioning circuitry takes the internal

parallel data bus and converts it to a serial data format at

DOUT, with the appropriate wake-up timing. The arith-

metic logic unit (ALU) performs the averaging function.

SPI-Compatible Serial Interface

The MAX1040âMAX1043/MAX1046âMAX1049 feature a

serial interface that is compatible with SPI and

MICROWIRE devices. For SPI, ensure the SPI bus mas-

ter (typically a microcontroller (ÂµC)) runs in master

mode so that it generates the serial clock signal. Select

the SCLK frequency of 25MHz or less, and set the

clock polarity (CPOL) and phase (CPHA) in the ÂµC con-

trol registers to the same value. The MAX1040â

MAX1043/MAX1046âMAX1049 operate with SCLK

idling high or low, and thus operate with CPOL = CPHA

= 0 or CPOL = CPHA = 1. Set CS low to latch any input

data at DIN on the falling edge of SCLK. Output data at

DOUT is updated on the falling edge of SCLK in clock

modes 00, 01, and 10. Output data at DOUT is updated

on the rising edge of SCLK in clock mode 11. See

Figures 6â11. Bipolar true-differential results and tem-

perature-sensor results are available in twoâs comple-

ment format, while all other results are in binary.

A high-to-low transition on CS initiates the data-input

operation. Serial communications to the ADC always

begin with an 8-bit command byte (MSB first) loaded

from DIN. The command byte and the subsequent data

bytes are clocked from DIN into the serial interface on

the falling edge of SCLK. The serial-interface and fast-

interface circuitry is common to the ADC, DAC, and

GPIO sections. The content of the command byte

determines whether the SPI port should expect 8, 16, or

24 bits and whether the data is intended for the ADC,

DAC, or GPIOs (if applicable). See Table 1. Driving CS

high resets the serial interface.

The conversion register controls ADC channel selec-

tion, ADC scan mode, and temperature-measurement

requests. See Table 4 for information on writing to the

conversion register. The setup register controls the

clock mode, reference, and unipolar/bipolar ADC con-

figuration. Use a second byte, following the first, to

write to the unipolar-mode or bipolar-mode registers.

See Table 5 for details of the setup register and see

Tables 6, 7, and 8 for setting the unipolar- and bipolar-

mode registers. Hold CS low between the command

byte and the second and third byte. The ADC averag-

ing register is specific to the ADC. See Table 9 to

address that register. Table 11 shows the details of the

reset register.

Begin a write to the DAC by writing 0001XXXX as a

command byte. The last 4 bits of this command byte

are donât-care bits. Write another 2 bytes (holding CS

low) to the DAC interface register following the com-

mand byte to select the appropriate DAC and the data

to be written to it. See the DAC Serial Interface section

and Tables 10, 17, and 18.

Write to the GPIOs (if applicable) by issuing a com-

mand byte to the appropriate register. Writing to the

MAX1042/MAX1043/MAX1048/MAX1049 GPIOs

requires 1 additional byte following the command byte.

18 ______________________________________________________________________________________

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