HSMS-270B [AVAGO]

High Performance Schottky Diode for Transient Suppression;


型号：	HSMS-270B
厂家：	AVAGO TECHNOLOGIES LIMITED
描述：	High Performance Schottky Diode for Transient Suppression 二极管
文件：	总9页 (文件大小：150K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

HSMS-2700, 2702, 270B, 270C, 270P

High Performance Schottky Diode

for Transient Suppression

Data Sheet

Description

Features

• Ultra-low Series Resistance for Higher Current

The HSMS-2700 series of Schottky diodes, commonly

referred to as clipping/clamping diodes, are optimal for

circuit and waveshape preservation applications with

high speed switching. Ultra-low series resistance, R_S,

makes them ideal for protecting sensitive circuit elements

against higher current transients carried on data lines.

With picosecond switching, the HSMS-270x can respond

to noise spikes with rise times as fast as 1 ns. Low ca-

pacitance minimizes waveshape loss that causes signal

degradation.

Handling

• Picosecond Switching

• Low Capacitance

• Lead-free

Applications

RF and computer designs that require circuit protection,

high-speed switching, and voltage clamping.

HSMS-270x DC Electrical Speciﬁcations, T_A= +25°C^[1]

Maximum Minimum

Typical

Series

Maximum

Eﬀ. Carrier

Part

Package

Forward

Voltage

V_F(mV)

Breakdown Typical

Voltage

V_BR(V)

Number Marking Lead

Capacitance Resistance Lifetime

HSMS-

Code^[2]

Code Conﬁguration Package

C_T(pF)

R_S(Ω)

τ (ps)

-2700

Single

SOT-23

SOT-323

(3-lead SC-70)

-270B

-2702

-270C

SOT-23

550^[3]

15^[4]

6.7^[5]

0.65

100^[6]

SOT-323

(3-lead SC-70)

Series

SOT-363

(6-lead SC-70)

-270P

Notes:

Bridge Quad

1. T_A= +25°C, where T_Ais deﬁned to be the temperature at the package pins where contact is made to the circuit board.

2. Package marking code is laser marked.

3. I_F= 100 mA; 100% tested

4. I_R= 100 μA; 100% tested

5. V_F= 0; f =1 MHz

6. Measured with Karkauer method at 20 mA; guaranteed by design.

Package Lead Code Identiﬁcation (Top View)

SINGLE

SERIES

BRIDGE QUAD

0, B

2, C

Absolute Maximum Ratings, T_A= 25ºC

Absolute Maximum^[1]

Symbol

I_F

Parameter

Unit

HSMS-2700/-2702

HSMS-270B/270C/270P

DC Forward Current

350

750

I_F-peak

P_T

Peak Surge Current (1μs pulse)

Total Power Dissipation

Peak Inverse Voltage

1.0

250

825

P_INV

T_J

Junction Temperature

Storage Temperature

Thermal Resistance, junction to lead

°C

150

T_STG

θ_JC

°C

-65 to 150

500

-65 to 150

150

°C/W

Note:

1. Operation in excess of any one of these conditions may result in permanent damage to the device.

Linear and Non-linear SPICE Model

SPICE Parameters

0.08 pF

Parameter

Unit

Value

CJO

IBV

6.7

0.55

10E-4

1.4E-7

1.04

0.65

0.6

2 nH

SPICE model

0.5

Typical Performance

300

100

500

100

160

140

120

100

Max. safe junction temp.

T_A= +75 C

T_A= +25 C

T_A= –25 C

0.1

T_A= +75 C

T_A= +25 C

T_A= –25 C

T_A= +75 C

T_A= +25 C

T_A= –25 C

0.01

0.1

0.2

0.3

0.4

0.5

0.6

0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8

100 150

300 350

200 250

V – FORWARD VOLTAGE (V)

I – FORWARD CURRENT (mA)

Figure 1. Forward Current vs. Forward Voltage at

Temperature for HSMS-2700 and HSMS-2702.

Figure 2. Forward Current vs. Forward Voltage at

Temperature for HSMS-270B and HSMS-270C.

Figure 3. Junction Temperature vs. Forward Current

as a Function of Heat Sink Temperature for the

HSMS-2700 and HSMS-2702.

Note: Data is calculated from SPICE parameters.

160

Max. safe junction temp.

T_A= +75 C

140

T_A= +25 C

120

100

T_A= –25 C

150

300

450

600

750

I – FORWARD CURRENT (mA)

V – REVERSE VOLTAGE (V)

Figure 4. Junction Temperature vs. Current as a

Figure 5. Total Capacitance vs. Reverse Voltage.

Function of Heat Sink Temperature for HSMS-270B

and HSMS-270C.

Note: Data is calculated from SPICE parameters.

Package Dimensions

Device Orientation

For Outlines SOT-23/323

Outline SOT-23

REEL

CARRIER

TAPE

XXX

USER

FEED

DIRECTION

COVER TAPE

TOP VIEW

END VIE W

4 mm

DIMENSIONS (mm)

SYMBOL

MIN.

0.79

0.000

0.30

0.08

2.73

1.15

0.89

1.78

0.45

2.10

0.45

MAX.

1.20

0.100

0.54

0.20

3.13

1.50

1.02

2.04

0.60

2.70

0.69

8 mm

ABC

Note: "AB" represents package marking code.

"C" represents date code.

Notes:

XXX-package marking

Drawings are not to scale

Recommended PCB Pad Layout

For Avago’s SOT-23 Products

Tape Dimensions and Product Orientation

For Outline SOT-23

0.039

0.079

2.0

0.035

0.9

13.5° MAX

8° MAX

9° MAX

0.031

0.8

inches

Dimensions in

DESCRIPTION

SYMBOL

SIZE (mm)

SIZE (INCHES)

CAVITY

LENGTH

WIDTH

DEPTH

PITCH

3.15 0.10

2.77 0.10

1.22 0.10

4.00 0.10

1.00 + 0.05

0.124 0.004

0.109 0.004

0.048 0.004

0.157 0.004

0.039 0.002

BOTTOM HOLE DIAMETER

PERFORATION

CARRIER TAPE

DIAMETER

PITCH

POSITION

1.50 + 0.10

4.00 0.10

1.75 0.10

0.059 + 0.004

0.157 0.004

0.069 0.004

WIDTH

8.00+0.30–0.10 0.315+0.012–0.004

THICKNESS

0.229 0.013

0.009 0.0005

DISTANCE

BETWEEN

CAVITY TO PERFORATION

(WIDTH DIRECTION)

3.50 0.05

0.138 0.002

CENTERLINE

CAVITY TO PERFORATION

(LENGTH DIRECTION)

2.00 0.05

0.079 0.002

Package Dimensions

Recommended PCB Pad Layout

For Avago’s SC70 3L/SOT-323 Products

Outline SOT-323 (SC-70 3 Lead)

0.026

XXX

0.079

0.039

0.022

DIMENSIONS (mm)

SYMBOL

MIN.

0.80

0.00

0.15

0.08

1.80

1.10

MAX.

1.00

0.10

0.40

0.25

2.25

1.40

Dimensions in inches

0.65 typical

1.30 typical

Notes:

1.80

0.26

2.40

0.46

XXX-package marking

Drawings are not to scale

Outline SOT-363 (SC-70 6 Lead)

DIMENSIONS (mm)

SYMBOL

MIN.

1.15

1.80

0.80

0.00

MAX.

1.35

2.25

2.40

1.10

1.00

0.10

0.650 BCS

0.15

0.08

0.10

0.30

0.25

0.46

Tape Dimensions and Product Orientation

For Outline SOT-323/363 (SC-70 3 and 6 Lead)

(CARRIER TAPE THICKNESS)

T (COVER TAPE THICKNESS)

8° MAX.

DESCRIPTION

SYMBOL

SIZE (mm)

SIZE (INCHES)

CAVITY

LENGTH

WIDTH

DEPTH

PITCH

2.40 0.10

1.20 0.10

4.00 0.10

1.00 + 0.25

0.094 0.004

0.047 0.004

0.157 0.004

0.039 + 0.010

BOTTOM HOLE DIAMETER

PERFORATION

DIAMETER

PITCH

POSITION

1.55 0.05

4.00 0.10

1.75 0.10

0.061 0.002

0.157 0.004

0.069 0.004

CARRIER TAPE

COVER TAPE

DISTANCE

WIDTH

THICKNESS

8.00 0.30

0.254 0.02

0.315 0.012

0.0100 0.0008

WIDTH

TAPE THICKNESS

5.4 0.10

0.062 0.001

0.205 0.004

0.0025 0.00004

CAVITY TO PERFORATION

(WIDTH DIRECTION)

3.50 0.05

0.138 0.002

CAVITY TO PERFORATION

(LENGTH DIRECTION)

2.00 0.05

0.079 0.002

Another signiﬁcant diﬀerence between Schottky and p-n

diodes is the forward voltage drop. Schottky diodes have

a threshold of typically 0.3 V in comparison to that of 0.6 V

in p-n junction diodes. See Figure 6.

Applications Information

Schottky Diode Fundamentals

The HSMS-270x series of clipping/clamping diodes

are Schottky devices. A Schottky device is a rectifying,

metal-semiconductor contact formed between a metal

and an n-doped or a p-doped semiconductor. When a

metal-semiconductor junction is formed, free electrons

ﬂow across the junction from the semiconductor and ﬁll

the free-energy states in the metal. This ﬂow of electrons

creates a depletion or potential across the junction. The

diﬀerence in energy levels between semiconductor and

metal is called a Schottky barrier.

Through the careful manipulation of the diameter of the

Schottky contact and the choice of metal deposited on

the n-doped silicon, the important characteristics of the

diode (junction capacitance, C_J; parasitic series resistance,

R_S; breakdown voltage, V_BR; and forward voltage, V_F,)

can be optimized for speciﬁc applications. The HSMS-

270x series and HBAT-540x series of diodes are a case in

point.

Both diodes have similar barrier heights; and this is

indicated by corresponding values of saturation current,

I_S. Yet, diﬀerent contact diameters and epitaxial-layer

thickness result in very diﬀerent values of C_Jand R_S. This

is seen by comparing their SPICE parameters in Table 1.

P-doped, Schottky-barrier diodes excel at applications

requiring ultra low turn-on voltage (such as zero-biased

RF detectors). But their very low, breakdown-voltage

and high series-resistance make them unsuitable for

the clipping and clamping applications involving high

forward currents and high reverse voltages. Therefore,

this discussion will focus entirely on n-doped Schottky

diodes.

Table 1. HSMS-270x and HBAT-540x SPICE Parameters.

Parameter

HSMS- 270x

25 V

HBAT- 540x

40 V

CJ0

IBV

Under a forward bias (metal connected to positive in an

n-doped Schottky), or forward voltage, V_F, there are many

electrons with enough thermal energy to cross the barrier

potential into the metal. Once the applied bias exceeds

the built-in potential of the junction, the forward current,

I_F, will increase rapidly as V_Fincreases.

6.7 pF

0.55 eV

10E-4 A

1.4E-7 A

1.04

3.0 pF

0.55 eV

10E-4 A

1.0E-7 A

1.0

0.65 Ω

0.6 V

2.4 Ω

0.6 V

When the Schottky diode is reverse biased, the potential

barrier for electrons becomes large; hence, there is a

small probability that an electron will have suﬃcient

thermal energy to cross the junction. The reverse leakage

current will be in the nanoampere to microampere range,

depending upon the diode type, the reverse voltage, and

the temperature.

0.5

At low values of I_F≤ 1 mA, the forward voltages of the

two diodes are nearly identical. However, as current rises

above 10 mA, the lower series resistance of the HSMS-

270x allows for a much lower forward voltage. This gives

the HSMS-270x a much higher current handling capabil-

ity. The trade-oﬀ is a higher value of junction capacitance.

The forward voltage and current plots illustrate the

diﬀerences in these two Schottky diodes, as shown in

Figure 7.

In contrast to a conventional p-n junction, current in

the Schottky diode is carried only by majority carriers

(electrons). Because no minority-carrier (hole) charge

storage eﬀects are present, Schottky diodes have carrier

lifetimes of less than 100 ps. This extremely fast switching

time makes the Schottky diode an ideal rectiﬁer at fre-

quencies of 50 GHz and higher.

300

HSMS-270x

100

METAL N

HBAT-540x

CAPACITANCE

CURRENT

0.3V

CAPACITANCE

0.6V

–

BIAS VOLTAGE

PN JUNCTION

SCHOTTKY JUNCTION

.01

0.1

0.2

0.3

0.4

0.5

0.6

Figure 6.

– FORWARD VOLTAGE (V)

Figure 7. Forward Current vs. Forward Voltage at 25°C.

Because the automatic, pick-and-place equipment used tained at a low limit even at high values of current.

to assemble these products selects dice from adjacent

Maximum reliability is obtained in a Schottky diode when

sites on the wafer, the two diodes which go into the

the steady state junction temperature is maintained at or

HSMS-2702 or HSMS-270C (series pair) are closely

below 150°C, although brief excursions to higher junction

matched—without the added expense of testing and

temperatures can be tolerated with no signiﬁcant impact

binning.

upon mean-time-to-failure, MTTF. In order to compute

the junction temperature, Equations (1) and (3) below

must be simultaneously solved.

Current Handling in Clipping/Clamping Circuits

The purpose of a clipping/clamping diode is to handle

high currents, 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.

11600 (V_F– I R_S)

(1)

I_F= I_S

–1

T_J

298

noisy data-spikes

–

–4060

T_J

298

(2)

(3)

current

I_S= I₀

limiting

T_J= V_FI_Fꢀ_JC+ T_A

long cross-site cable

pull-down

where:

(or pull-up)

I_F= forward current

voltage limited to

Vs + Vd

0V – Vd

I_S= saturation current

V_F= forward voltage

R_S= series resistance

T_J= junction temperature

Figure 8. Two Schottky Diodes Are Used for Clipping/Clamping in a Circuit.

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.

I_O= saturation current at 25°C

n = diode ideality factor

θ_JC= thermal resistance from junction to case (diode

lead)

= θ_package+ θ_chip

T_A= ambient (diode lead) temperature

Equation (1) describes the forward V-I curve of a Schottky

diode. Equation (2) provides the value for the diode’s satu-

ration 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.

= 7.7

= 1.0

0.3

The key factors in these equations are: R_S, the series resis-

tance of the diode where heat is generated under high

current conditions; θ_chip, the chip thermal resistance of

the Schottky die; and θ_package, or the package thermal

resistance.

0.1

0.2

0.4

0.5

– FORWARD CURRENT (mA)

Figure 9. Comparison of Two Diodes.

R_Sfor the HSMS-270x family of diodes is typically 0.7 Ω

and is the lowest of any Schottky diode available from

Avago. Chip thermal resistance is typically 40°C/W; the

thermal resistance of the iron-alloy-leadframe, SOT-23

package is typically 460°C/W; and the thermal resistance

of the copper-leadframe, SOT-323 package is typically

110°C/W. The impact of package thermal resistance on

the current handling capability of these diodes can be

seen in Figures 3 and 4. Here the computed values of

junction temperature vs. forward current are shown

The ﬁrst is a conventional Schottky diode of the type

generally used in RF circuits, with an R_Sof 7.7 Ω. The

second is a Schottky diode of identical characteristics,

save the R_Sof 1.0 Ω. For the conventional diode, the

relatively high value of R_Scauses the voltage across the

diode’s terminals to rise as current increases. The power

dissipated in the diode heats the junction, causing R_Sto

climb, giving rise to a runaway thermal condition. In the

second diode with low R_S, such heating does not take

place and the voltage across the diode terminals is main-

for three values of ambient temperature. The SOT-323

products, with their copper leadframes, can safely handle

almost twice the current of the larger SOT-23 diodes.

Note that the term “ambient temperature” refers to the

temperature of the diode’s leads, not the air around the

circuit board. It can be seen that the HSMS-270B and

HSMS-270C products in the SOT-323 package will safely

withstand a steady-state forward current of 550 mA when

the diode’s terminals are maintained at 75°C.

Part Number Ordering Information

Part Number

No. of Devices

Container

HSMS-2700-BLKG

HSMS-2700-TR1G

HSMS-2700-TR2G

100

3,000

10,000

Antistatic Bag

7" Reel

13" Reel

HSMS-2702-BLKG

HSMS-2702-TR1G

HSMS-2702-TR2G

100

3,000

10,000

Antistatic Bag

7" Reel

13" Reel

HSMS-270B-BLKG

HSMS-270B-TR1G

HSMS-270B-TR2G

100

3,000

10,000

Antistatic Bag

7" Reel

13" Reel

For pulsed currents and transient current spikes of less

than one microsecond in duration, the junction does not

have time to reach thermal steady state. Moreover, the

diode junction may be taken to temperatures higher than

150°C for short time-periods without impacting device

MTTF. Because of these factors, higher currents can be

safely handled. The HSMS-270x family has the highest

current handling capability of any Avago diode.

HSMS-270C-BLKG

HSMS-270C-TR1G

HSMS-270C-TR2G

100

3,000

10,000

Antistatic Bag

7" Reel

13" Reel

HSMS-270P-BLKG

HSMS-270P-TR1G

100

3,000

Antistatic Bag

7" Reel

For product information and a complete list of distributors, please go to our web site: www.avagotech.com

Avago, Avago Technologies, and the A logo are trademarks of Avago Technologies Limited in the United States and other countries.

AV02-1366EN - July 7, 2010

HSMS-270B [AVAGO]

相关型号：

HSMS-270B-BLK

HSMS-270B-BLK

HSMS-270B-BLKG

HSMS-270B-TR1

HSMS-270B-TR1

HSMS-270B-TR1G

HSMS-270B-TR1G

HSMS-270B-TR2

HSMS-270B-TR2

HSMS-270B-TR2G

HSMS-270C

HSMS-270C