HBAT-540F Hewlett-Packard, HBAT-540F Datasheet - Page 7

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HBAT-540F

Manufacturer Part Number

HBAT-540F

Description

(HBAT-540x) High Performance Schottky Diode

Manufacturer

Hewlett-Packard

Datasheet

1.HBAT-540F.pdf (8 pages)

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Figure 7. Forward Current vs.

Forward Voltage at 25°C.

Because the automatic, pick-and-

place equipment used to assemble

these products selects dice from

adjacent sites on the wafer, the

two diodes which go into the

HBAT-5402 or HBAT-540C (series

pair) are closely matched —

without the added expense of

testing and binning.

Current Handling in Clipping/

Clamping Circuits

The purpose of a clipping/clamp-

ing diode is to handle high cur-

rents, protecting delicate circuits

downstream of the diode. Current

handling capacity is determined

by two sets of characteristics,

those of the chip or device itself

and those of the package into

which it is mounted.

noisy data-spikes

long cross-site cable

Figure 8. Two Schottky Diodes

Are Used for Clipping/Clamping in

a Circuit.

300

100

.01

10

.1

1

pull-down

(or pull-up)

0

V

0.1

F

– FORWARD VOLTAGE (V)

0.2

current

limiting

HSMS-270x

0.3

0V

voltage limited to

Vs + Vd

0V – Vd

0.4

Vs

HBAT-540x

0.5

0.6

Consider the circuit shown in

Figure 8, in which two Schottky

diodes are used to protect a

circuit from noise spikes on a

stream of digital data. The ability

of the diodes to limit the voltage

spikes is related to their ability to

sink the associated current spikes.

The importance of current

handling capacity is shown in

Figure 9, where the forward

voltage generated by a forward

current is compared in two

diodes. The first is a conventional

Schottky diode of the type gener-

ally used in RF circuits, with an R

of 7.7 Ω. The second is a Schottky

diode of identical characteristics,

save the R

conventional diode, the relatively

high value of R

voltage across the diode’s termi-

nals to rise as current increases.

The power dissipated in the diode

heats the junction, causing R

climb, giving rise to a runaway

thermal condition. In the second

diode with low R

does not take place and the

voltage across the diode terminals

is maintained at a low limit even

at high values of current.

Maximum reliability is obtained in

a Schottky diode when the steady

state junction temperature is

maintained at or below 150°C,

although brief excursions to

higher junction temperatures can

be tolerated with no significant

impact upon mean-time-to-failure,

MTTF. In order to compute the

junction temperature, Equations

(1) and (3) below must be simulta-

neously solved.

S

of 1.0 Ω. For the

S

causes the

S

, such heating

S

to

S

I

I

T

where:

I

I

V

R

T

I

n = diode ideality factor

θ

junction to case (diode lead)

T

temperature

Equation (1) describes the for-

ward V-I curve of a Schottky

diode. Equation (2) provides the

value for the diode’s saturation

current, which value is plugged

into (1). Equation (3) gives the

value of junction temperature as a

function of power dissipated in

the diode and ambient (lead)

temperature.

Figure 9. Comparison of Two

Diodes.

F

S

F

S

O

J

J

JC

F

A

S

= I

= I

= forward current

= saturation current

= junction temperature

= saturation current at 25°C

= V

= θ

= forward voltage

= series resistance

= ambient (diode lead)

= thermal resistance from

S

0

6

5

4

3

2

1

0

7

F

0

package

e

298

11600 (V

I

T

F

I

J

F

θ

– FORWARD CURRENT (mA)

0.1

JC

2

n

+ θ

+ T

e

nT J

–4060

F

0.2

A

chip

– I

R

R

s

s

= 7.7 Ω

= 1.0 Ω

F

0.3

R

T J

S

1

)

–

–1

298

0.4

1

(1)

(2)

(3)

0.5

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