MAX5661EVCMAXQU+ Maxim Integrated Products, MAX5661EVCMAXQU+ Datasheet - Page 34

MAX5661EVCMAXQU+

Manufacturer Part Number

MAX5661EVCMAXQU+

Description

EVALUATION SYSTEM FOR MAX56611

Manufacturer

Maxim Integrated Products

Datasheets

1.MAX5661GCB.pdf (40 pages)

2.MAX5661EVKIT.pdf (13 pages)

Specifications of MAX5661EVCMAXQU+

Number Of Dac's

Number Of Bits

Outputs And Type

2, Single Ended

Data Interface

Serial

Dac Type

Current/Voltage

Voltage Supply Source

Single

Operating Temperature

-40°C ~ 105°C

Utilized Ic / Part

MAX5661

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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After setting the MAX5661 for 0 to 20mA current-range

mode, determine the LSB size as follows:

1) Measure I

2) Measure I

3) Measure I

If I

(code 192) is inside the linear region of the I

fer curve.

Obtain the straight-line equation from I

in the equation:

The expected current is -30µA (typ).

After connecting all ground inputs, apply the analog

supply voltages V

supply, the second most positive supply, etc. Before

applying power, connect the V

whether the current output or voltage output is used. Do

not apply V

(Table 16). Ensure that there are no unconnected

power-supply connections when powering the

MAX5661. If V

Schottky diode between V

Single 16-Bit DAC with Current and Voltage

Outputs for Industrial Analog Output Modules

Table 16. Application Modes and Supply-Voltage Limits

* On-the-fly switching. Only one output is active at a time.

OUT

Voltage from OUTV

Current from OUTI

(Single Supply)

Voltage from OUTV and Current

from OUTI*

DDV

Power-Supply Sequencing and Bypassing

OUT

_______________________________________________________________________________________

(192) and substituting code 0 for I

(

I I

APPLICATION MODE

or V

−

at ZS

(code 193) - I

OUT

SSV

DDI

LSB

OUT

DDCORE

(

or V

OUT

192

, as shown in Table 16, depending on

SSV

Applications Information

)

at full scale (FS).

at code 192.

at code 193:

Measuring Zero-Code Current

SSV

DDI

OUT

⎛

⎜

⎝

192

cannot be powered first, connect a

OUT

) in the preferred configuration

OUT

first followed by the most positive

separate from the main supply

−

(

at FS

at FS I

65535 192

OUT

SSV

(code 192) > 0.5 I

−

at FS x

−

)

OUT

−

and AGND.

OUT

DDCORE

−

)

(0 to 20mA Mode)

192

+13.48V to +15.75V

a a t

0 002 2 9383

192

⎞

⎟

⎠

OUT

AGND

x code

supply to either

DDV

(

OUT

+ I

(zero scale)

OUT

LSB

−

(FS) and

192

, I

trans-

)

192

OUT

-13.48V to -15.75V

AGND

In standard SPI-/QSPI-/MICROWIRE-compatible sys-

tems, a microcontroller (µC) communicates with its

slave devices through a 3- or 4-wire serial interface.

The typical interface includes a chip select signal (CS),

a serial clock (SCLK), a data input signal (DIN), and

sometimes a data signal output (DOUT). In this system,

the µC allots an independent chip-select signal to each

slave device so that they can be addressed individually

(see Figure 10). Only the slaves with their CS inputs

asserted low acknowledge and respond to the activity

on the serial clock and data lines. This is simple to

implement when there are very few slave devices in the

system. An alternative programming method is daisy

chaining. Daisy chaining, in serial-interface applica-

tions, is a method of propagating commands through

multiple devices connected in series (see Figure 11).

Daisy chaining reduces CS and DIN line routing, and

saves board space when using the MAX5661.

Daisy chain multiple MAX5661 devices by connecting

the DOUT of one device to the DIN of the next. Connect

the SCLK of all devices to a common clock and connect

the CS from all devices to a common chip-select line.

Data shifts out of DOUT 24.5 clock cycles after it is shift-

ed into DIN on the falling edge of SCLK. Hold CS low

until each slave in the chain receives its 24-bit word (8

command bits and 16 data bits). In this configuration,

the µC only needs three signals (CS, SCLK, and DIN) to

control all the slaves in the network. The SPI-/QSPI-

/MICROWIRE-compatible serial interface normally works

at up to 10MHz, but must be slowed to 6MHz if daisy

chaining. DOUT is high impedance when CS is high.

Figure 10 details a method of controlling multiple

MAX5661 devices using separate CS lines. This

method allows writes to and reads from each device

without shifting data through the other device’s shift

together. This configuration requires a read from each

device to determine which one has the fault condition

and saves an optocoupler in isolated applications. It is

not necessary to short the FAULT outputs together.

Daisy Chaining Multiple MAX5661 Devices

SSV

+13.48V to +40V

DDV

DDI

to +40V

DDCORE

DDV

DDI

MAX5661EVCMAXQU+ Maxim Integrated Products, MAX5661EVCMAXQU+ Datasheet - Page 34

MAX5661EVCMAXQU+

Specifications of MAX5661EVCMAXQU+

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