MAXQ3183-RAN+ Maxim Integrated Products, MAXQ3183-RAN+ Datasheet - Page 68

MAXQ3183-RAN+

Manufacturer Part Number

MAXQ3183-RAN+

Description

IC AFE POLYPHASE MULTI 28TSSOP

Manufacturer

Maxim Integrated Products

Datasheet

1.MAXQ3183-RAN.pdf (102 pages)

Specifications of MAXQ3183-RAN+

Number Of Channels

Power (watts)

140mW

Voltage - Supply, Analog

3.6V

Voltage - Supply, Digital

3.6V

Package / Case

28-TSSOP

For Use With

MAXQ3183-KIT - KIT EV REFRNC DSIGN FOR MAXQ3183

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Number Of Bits

Other names

90-M3183+RAN

Current page: 68 of 102
Download datasheet (2Mb)

Low-Power, Multifunction, Polyphase AFE

with Harmonics and Tamper Detect

The second consideration is the total power dissipation

and voltage hold-off requirements of the resistor. It is

tempting to design a 400:1 divider with a 400kΩ resis-

tor in series with a 1kΩ resistor, but that would force the

400kΩ resistor to dissipate about 140mW. This is not an

excessive amount of power, but if the design is to use

small SMT parts, it can handle greater than a 1/10W

SMT resistor. It is better to use a series of several small-

er components to improve system reliability.

If isolation is required between the meter electronics

and the line, a voltage transformer is required. A volt-

age transformer is designed to faithfully transfer an AC

voltage applied on the primary side to a sensor on the

secondary side. On the primary side, a voltage-divider

is used to reduce the voltage to a workable level. On

the secondary side, a load resistor is selected so that

the current in the transformer windings is safely within

the transformer’s linear operating region.

Because the impedance seen in the primary side of the

transformer is equal to the impedance of the load resis-

tor in the secondary circuit plus impedance of the

transformer secondary winding at the operating fre-

quency, it is easy to calculate the value of the required

voltage-divider resistors in the primary side. For exam-

ple, assume we want a 500:1 divider ratio and assume

the load resistor is 600Ω and that the impedance of the

transformer secondary is 200Ω. The resistor required in

the primary is

Often, this resistor is constructed from multiple

instances of a smaller value resistor; in this case, one

might use eight 50kΩ resistors. Doing so minimizes the

voltage requirements for the resistor chain and reduces

the possibility that a single point of failure will cause a

catastrophic failure.

A current shunt is a low-value (approximately 100μΩ to

a 100mΩ) resistor that converts a large-value current

into a small voltage. Shunts make good current sensors

because the output is an extremely linear representa-

tion of the measured current, current shunts can have

very low temperature coefficients, and they are inex-

pensive.

The power dissipated by a current shunt is inversely

proportional to its resistance and proportional to the

square of the output voltage. Consequently, there is

great incentive to reduce the resistance (and hence,

the output voltage) of a shunt. Often, full-scale current

______________________________________________________________________________________

(600 + 200) x 500 = 400kΩ

Voltage Transformer

Current Sensors

Current Shunt

in a shunt produces only a few millivolts of output, mak-

ing a front-end amplifier essential. The MAXQ3183

includes a gain-of-32 amplifier in the current channels

that is automatically cycled in and out, depending on

the input voltage of the current channels.

Current shunts operate at line voltage, thus, the AFE

must be isolated from the line. That means that in a

wye-connected meter, the current sensing must be per-

formed in the neutral return circuit (so that all voltages

into the current-sense amplifiers are referenced to neu-

tral). It also means that the use of a shunt is precluded

for delta-connected meters; the MAXQ3183 cannot tol-

erate the line-voltage differential between channels.

In a current transformer, the primary is usually one turn

of thick wire or buss bar and the secondary is often

1000 turns or more of magnet wire. A ferrite core mag-

netically couples the two. Thus, a large current in the

primary turn creates a small current but large voltage in

the secondary winding.

For example, assume a current transformer with a 1000

turn secondary. A 10A current in the primary winding

induces a 10mA current in the secondary. This current

is made to flow through a so-called “burden” resistor,

usually 10Ω to 20Ω. Assuming a 20Ω burden, our 10A

current thus produces a 200mV signal in the secondary.

There are several other registers that directly affect the

AFE function. These registers directly affect the hard-

ware functionality, and should be modified only when it

is explicitly required. For example, if the MAXQ3183 is

operated at some frequency other than the nominal

8MHz system clock, modification of these registers by

supervisory code becomes necessary to maintain a

360μs frame time.

• R_ACFG: This register contains bits that disable the

• R_ADCRATE: Modify this register to change the rate

ADC entirely, disable the voltage reference buffer

amplifier, and disable the ADC interrupt. Modifying

this register will likely disable or impair operation of

the MAXQ3183 internal firmware.

at which the MAXQ3183 acquires samples. By

default, R_ADCRATE contains 359 decimal, which

means that the ADC acquires a sample every 360

system clocks. With an 8MHz clock, this translates to

45μs. If the system clock is slower, it may be advan-

tageous to reduce this value to keep a 45μs per sam-

ple time constant.

Modifying the ADC Operation

Advanced Operation

Current Transformer

MAXQ3183-RAN+ Maxim Integrated Products, MAXQ3183-RAN+ Datasheet - Page 68

MAXQ3183-RAN+

Specifications of MAXQ3183-RAN+

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