OPA2674 Datasheet, PDF(18/33 Page) Burr-Brown (TI) – Dual Wideband, High Output Current Operational Amplifier with Current Limit

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OPA2674 Datasheet, PDF (18/33 Pages) Burr-Brown (TI) – Dual Wideband, High Output Current Operational Amplifier with Current Limit

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OPA2674

SBOS270A â AUGUST 2003 â REVISED MAY 2006

OPA2674 HDSL2 UPSTREAM DRIVER

Figure 6 shows an HDSL2 implementation of a single-

supply driver.

20â¦

+12V

1/2

O PA 26 74

0.1ÂµF

324â¦

IP = 185mA

11.5â¦ 1:2.4

AFE +6V

2kâ¦

2VPP

Max

Assumed 0.1ÂµF 2kâ¦

82.5â¦

1ÂµF

324â¦

17.7VPP

11.5â¦

ZLine

135â¦

20â¦

1/2

O PA 26 74

IP = 185mA

Figure 6. HDSL2 Upstream Driver

The two designs differ by the values of the matching

impedance, the load impedance, and the ratio turns of the

transformers. All of these differences are reflected in the

higher peak current and thus, the higher maximum power

dissipation in the output of the driver.

LINE DRIVER HEADROOM MODEL

The first step in a driver design is to compute the

peak-to-peak output voltage from the target specifications.

This is done using the following equations:

PL + 10

log

V RMS 2

(1mW) RL

(3)

With PL power and VRMS voltage at the load, and RL load

impedance, this gives:

Ç¸ VRMS +

(1mW)

10 10

(4)

VP + CrestFactor VRMS + CF VRMS (5)

with VP peak voltage at the load and CF Crest Factor;

VLPP + 2 CF VRMS

(6)

with VLPP: peak-to-peak voltage at the load.

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Consolidating Equations 3 through 6 allows the required

peak-to-peak voltage at the load function of the crest

factor, the load impedance, and the power in the load to be

expressed. Thus:

VLPP + 2

Ç¸(1mW)

(7)

This VLPP is usually computed for a nominal line

impedance and may be taken as a fixed design target.

The next step for the driver is to compute the individual

amplifier output voltage and currents as a function of VPP

on the line and transformer turns ratio. As the turns ratio

changes, the minimum allowed supply voltage also

changes. The peak current in the amplifier is given by:

2 VLPP

4RM

(8)

With VLPP defined in Equation 7 and RM defined in

Equation 2. The peak current is computed in Figure 7 by

noting that the total load is 4RM and that the peak current

is half of the peak-to-peak calculated using VLPP.

Â±IP RM

1:n

2VLPP

VLPP

Â±IP

VLPP

Figure 7. Driver Peak Output Model

With the required output voltage and current versus turns

ratio set, an output stage headroom model will allow the

required supply voltage versus turns ratio to be developed.

The headroom model (see Figure 8) can be described with

the following set of equations:

First, as available output voltage for each amplifier:

VOPP + VCC * (V1 ) V2) * IP (R1 ) R2) (9)

Or, second, as required single-supply voltage:

VCC + VOPP ) (V1 ) V2) ) IP (R1 ) R2) (10)

The minimum supply voltage for a power and load

requirement is given by Equation 10.

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