Product specifications

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132

Power Products AC Power and Load Connections (Continued)

Applications Information

More detailed specifications at

www.agilent.com/find/power

e. Load system floated at a DC

potential above ground.

It is sometimes necessary to operate

the power supply output at a fixed

voltage above or below ground

potential. The usual procedure in

these circumstances is to designate

a DC common point using whichev-

er of the preceding four alternatives

is appropriate, just as though con-

ductive grounding were to be used.

Then connect this DC common point

to the DC ground point through a

1 microfarad capacitor as shown

in Figure 9.

Figure 9

Floating a load system at a DC potential

above ground

Select the DC Ground Point

STEP 6. Designate the terminal that

is connected to ground as the DC

ground point.

The DC ground point can be any

single terminal, existing or added,

that is conductively connected to the

ground of the building wiring system

and then eventually to earth ground.

STEP 7. Connect the DC common point

to the DC ground point, making cer-

tain there is only one conductive path

between these two points.

Make this connection as shown in

Figures 4, 5, 6, or 7. Make the con-

nection as short as possible and use

a wire size such that the total imped-

ance from the DC common point to

the DC ground point is not large

compared with the impedance from

the ground point to earth ground.

Flat braided leads are sometimes

used to further reduce the high

frequency component of the ground

lead impedance.

Making Remote Error Sensing

Connections

Normally a power supply operating

in the constant voltage mode

achieves its optimum line and load

regulation, its lowest output imped-

ance, drift, and PARD, and its fastest

transient recovery performance at

the power supply output terminals.

If the load is separated from the

output terminals by any lead length

(as in Figure 10), some of these

performance characteristics will be

degraded at the load terminals-

usually by an amount proportional

to the impedance of the load leads

compared with the output imped-

ance of the power supply.

Figure 10

Load voltage variations caused by load lead

voltage drops when remote error sensing is

not used

With remote error sensing, a feature

included in nearly all Agilent power

supplies, it is possible to connect the

input of the voltage feedback ampli-

fier directly to the load terminals

so that the regulator performs its

function with respect to the load

terminals rather than with respect to

the power supply output terminals.

Thus, the voltage at the power supply

output terminals shifts by whatever

amount is necessary to compensate

for the voltage drop in the load leads,

thereby maintaining the voltage at the

load terminals constant (Figure 11).

Figure 11

Regulated power supply with remote

error sensing

Power Supply

+S

Load

GND

S.G.

CP

GP

1µf

-S

+

-

Power Supply

+S

R

L

-S

↑

+

-

Power Supply

+ Sensing Lead

- Sensing Lead

+

R

L

-

+S

-S

↑