AD73360AR-REEL7 Analog Devices Inc, AD73360AR-REEL7 Datasheet - Page 27

AD73360AR-REEL7

Manufacturer Part Number

AD73360AR-REEL7

Description

IC ANALOG FRONT END 6CH 28-SOIC

Manufacturer

Analog Devices Inc

Datasheets

1.AD73360LARZ-REEL.pdf (35 pages)

2.AD73360LARZ-REEL.pdf (2 pages)

Specifications of AD73360AR-REEL7

Number Of Channels

Rohs Status

RoHS non-compliant

Number Of Bits

Power (watts)

80mW

Voltage - Supply, Analog

Voltage - Supply, Digital

Package / Case

28-SOIC (7.5mm Width)

Analog Front End Type

General Purpose

Analog Front End Category

General Purpose

Interface Type

Serial (6-Wire)

Sample Rate

64KSPS

Input Voltage Range

1.64375V

Operating Supply Voltage (min)

4.5V

Operating Supply Voltage (typ)

Operating Supply Voltage (max)

5.5V

Resolution

16b

Number Of Adc's

Power Supply Type

Analog/Digital

Operating Temp Range

-40C to 85C

Operating Temperature Classification

Industrial

Mounting

Surface Mount

Pin Count

Package Type

SOIC W

For Use With

EVAL-AD73360LEB - BOARD EVAL FOR AD73360L

Lead Free Status / RoHS Status

Not Compliant

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DSP SPORT Interrupts

If SPORT interrupts are enabled, it is important to note that the

active signals on the frame sync pins do not necessarily corre-

spond with the positions in time of where SPORT interrupts are

generated.

On ADSP-21xx processors, it is necessary to enable SPORT

interrupts and use Interrupt Service Routines (ISRs) to handle

Tx/Rx activity, while on the TMS320C5x processors it is pos-

sible to poll the status of the Rx and Tx registers, which means

that Rx/Tx activity can be monitored using a single ISR that

would ideally be the Tx ISR as the Tx interrupt will typically

occur before the Rx ISR.

APPLICATIONS EXAMPLES

Vector Motor Control

The current drawn by a motor can be split into two compo-

nents: one produces torque and the other produces magnetic

flux. For optimal performance of the motor, these two compo-

nents should be controlled independently. In conventional

methods of controlling a three-phase motor, the current (or

voltage) supplied to the motor and the frequency of the drive are

the basic control variables. However, both the torque and flux

are functions of current (or voltage) and frequency. This cou-

pling effect can reduce the performance of the motor because,

for example, if the torque is increased by increasing the fre-

quency, the flux tends to decrease.

Vector control of an ac motor involves controlling phase in

addition to drive and current frequency. Controlling the phase

of the motor requires feedback information on the position of

the rotor relative to the rotating magnetic field in the motor.

Using this information, a vector controller mathematically trans-

forms the three-phase drive currents into separate torque and

flux components. The AD73360, with its six-channel simulta-

neous sampling capability, is ideally suited for use in vector

motor control applications.

A block diagram of a vector motor control application using the

AD73360 is shown in Figure 30. The position of the field is

derived by determining the current in each phase of the motor.

information.

Simultaneous sampling is critical to maintain the relative phase

information between the channels. A current-sensing isolation

amplifier, transformer or Hall-effect sensor is used between the

motor and the AD73360. Rotor information is obtained by

measuring the voltage from the three inputs to the motor. V

tion. A DSP microprocessor is used to perform the mathematical

transformations and control loop calculations on the informa-

tion fed back by the AD73360.

REV. A

IN1

IN5

, V

and V

IN2

and V

IN6

of the AD73360 are used to obtain this informa-

IN3

of the AD73360 are used to digitize this

IN4

–27–

Industrial Power Metering

The AD73360 can be used to measure the voltage and current

in all three phases of a three-phase supply. The simultaneous

sampling architecture of the AD73360 is ideal for this applica-

tion where simultaneous sampling is critical to maintaining the

relative phase information between the three voltage and three

current phases. Figure 31 shows a block diagram of a three-

phase metering system. The V

used to measure the voltages in each phase (via voltage attenua-

tors). The current flowing in each phase can be detected by the

use of current-sensing isolation amplifiers, transformers or

Hall-effect sensors. V

this information. A DSP microprocessor is used to perform

the mathematical calculations on the information provided by

the AD73360.

SETPOINT

TORQUE

Figure 30. Vector Motor Control Using the AD73360

FLUX

SUPPLY

MICROPROCESSOR

THREE-

PHASE

Figure 31. Three-Phase Power Metering

TRANSFORMATION

MICROPROCESSOR

TORQUE & FLUX

CONTROL LOOP

CALCULATIONS

COMPONENTS

TO TORQUE &

DSP

CURRENT

FLUX

DSP

IN4

, V

IN5

AD73360

IN1

and V

DAC

AD73360

, V

IN1

IN2

IN3

IN4

IN5

IN6

IN2

AMPLIFIERS

ISOLATION

IN6

CIRCUITRY

AMPLIFIERS

IN1

IN2

IN3

IN4

IN5

IN6

and V

ATTENUATORS

DRIVE

ISOLATION

are used to digitize

VOLTAGE

ATTENUATORS

VOLTAGE

IN3

AD73360

channels are

THREE-

MOTOR

PHASE

AD73360AR-REEL7 Analog Devices Inc, AD73360AR-REEL7 Datasheet - Page 27

AD73360AR-REEL7

Specifications of AD73360AR-REEL7

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