AD5361 Analog Devices, AD5361 Datasheet - Page 20

AD5361

Manufacturer Part Number

AD5361

Description

16-Channel, 14-Bit, Serial Input, Voltage-Output DAC

Manufacturer

Analog Devices

Datasheet

1.AD5360.pdf (28 pages)

Specifications of AD5361

Resolution (bits)

14bit

Dac Update Rate

540kSPS

Dac Settling Time

20µs

Max Pos Supply (v)

+16.5V

Single-supply

Dac Type

Voltage Out

Dac Input Format

Ser,SPI

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Current page: 20 of 28
Download datasheet (815Kb)

AD5360/AD5361

MONITOR FUNCTION

The AD5360/AD5361 contain a channel monitor function

that consists of an analog multiplexer addressed via the serial

interface, allowing any channel output to be routed to this pin

for monitoring using an external ADC. In addition, two monitor

inputs, MON_IN0 and MON_IN1, are provided, which can also

be routed to MON_OUT. The monitor function is controlled by

the monitor register, which allows the monitor output to be

enabled or disabled, and selection of a DAC channel or one of

the monitor pins. When disabled, the monitor output is high

impedance, so several monitor outputs can be connected in

parallel and only one enabled at a time. Table 9 shows the

control register settings relevant to the monitor function.

Table 9. Control Register Monitor Functions

The multiplexer is implemented as a series of analog switches.

Because this could conceivably cause a large amount of current

to flow from the input of the multiplexer, that is, VOUTx or

MON_INx to the output of the multiplexer, MON_OUT, care

should taken to ensure that whatever is connected to the

MON_OUT pin is of high enough impedance to prevent the

continuous current limit specification from being exceeded.

Because the MON_OUT pin is not buffered, the amount of

current drawn from this pin creates a voltage drop across the

switches, which in turn leads to an error in the voltage being

monitored. Where accuracy is important, it is recommended

that the MON_OUT pin be buffered. Figure 20 shows the

typical error due to the MON_OUT current

GPIO PIN

The AD5360/AD5361 have a general-purpose I/O pin, GPIO.

This can be configured as an input or an output and read back

or programmed (when configured as an output) via the serial

interface. Typical applications for this pin include monitoring

the status of a logic signal, monitoring a limit switch, or

controlling an external multiplexer. The GPIO pin is configured

by writing to the GPIO register, which has the special function

code of 001101 (see Table 14 and Table 15 ). When Bit F1 is set,

the GPIO pin becomes an output and F0 determines whether

the pin is high or low. The GPIO pin can be set as an input by

writing 0 to both F1 and F0. The status of the GPIO pin can be

determined by initiating a read operation using the appropriate

bits in Table 16. The status of the pin is indicated by the LSB of

the register read.

Function

MON_OUT disabled

MON_OUT enabled

MON_OUT = VOUT0

MON_OUT = VOUT1

MON_OUT = VOUT15

MON_OUT = MON_IN0

MON_OUT = MON_IN1

Rev. A | Page 20 of 28

POWER-DOWN MODE

The AD5360/AD5361 can be powered down by setting Bit 0 in

the control register to 1. This turns off the DACs, thus reducing

the current consumption. The DAC outputs are connected to

their respective SIGGND potentials. The power-down mode

does not change the contents of the registers, and the DACs

return to their previous voltage when the power-down bit is

cleared to 0.

THERMAL MONITORING FUNCTION

The AD5360/AD5361 can be programmed to power down the

DACs if the temperature on the die exceeds 130°C. Setting Bit 1

in the control register to 1 (see Table 15) enables this function.

If the die temperature exceeds 130°C, the AD5360/AD5361

enter a temperature power-down mode, which is equivalent to

setting the power-down bit in the control register. To indicate

that the AD5360/AD5361 have entered temperature shutdown

mode, Bit 4 of the control register is set to 1. The AD5360/AD5361

remain in temperature shutdown mode, even if the die tempera-

ture falls, until Bit 1 in the control register is cleared to 0.

TOGGLE MODE

The AD5360/AD5361 have two X2 registers per channel, X2A

and X2B, which can be used to switch the DAC output between

two levels with ease. This approach greatly reduces the overhead

required by a microprocessor, which would otherwise have to

write to each channel individually. When the user writes to

either the X1A, X2A, M, or C register, the calculation engine

takes a certain amount of time to calculate the appropriate X2A

or X2B values. If the application only requires that the DAC

output switch between two levels, such as a data generator, any

method that reduces the amount of calculation time encoun-

tered is advantageous. For the data generator example, the user

should set the high and low levels for each channel once, by

writing to the X1A and X1B registers. The values of X2A and

X2B are calculated and stored in their respective registers. The

calculation delay, therefore, only happens during the setup

phase, that is, when programming the initial values. To toggle a

DAC output between the two levels, it is only required to write

to the relevant A /B select register to set the MUX 2 register bit.

Furthermore, because there are eight MUX 2 control bits per

write.

output.

Table 17

shows the bits that correspond to each DAC

AD5361 Analog Devices, AD5361 Datasheet - Page 20

AD5361

Specifications of AD5361

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