HSMS-2860-TR1 - Avago Technologies - Datasheet.Technology

HSMS-286x Series

Surface Mount Microwave Schottky Detector Diodes

Data Sheet

SOT-23/SOT-143 Package Lead Code Identiﬁcation

(top view)

Description

Avago’s HSMS‑286x family of DC biased detector diodes

have been designed and optim ized for use from 915 MHz

to 5.8 GHz. They are ideal for RF/ID and RF Tag applications

as well as large signal detection, modulation, RF to DC

conversion or voltage doubling.

Available in various package con ﬁgurations, this family

of detector diodes provides low cost solutions to a wide

variety of design problems. Avago’s manufacturing

techniques assure that when two or more diodes are

mounted into a single surface mount package, they

are taken from adjacent sites on the wafer, assuring the

highest possible degree of match.

Pin Connections and Package Marking

SOT-323 Package Lead Code Identiﬁcation (top view)

Notes:

1. Package marking provides orientation and identiﬁcation.

2. The ﬁrst two characters are the package marking code.

The third character is the date code.

Features

• Surface Mount SOT‑23/SOT‑143 Packages

• Miniature SOT‑323 and SOT‑363 Packages

• High Detection Sensitivity:

up to 50 mV/µW at 915 MHz

up to 35 mV/µW at 2.45 GHz

up to 25 mV/µW at 5.80 GHz

• Low FIT (Failure in Time) Rate*

• Tape and Reel Options Available

• Unique Conﬁgurations in Surface Mount SOT‑363

Package

– increase ﬂexibility

– save board space

– reduce cost

• HSMS‑286K Grounded Center Leads Provide up to

10 dB Higher Isolation

• Matched Diodes for Consistent Performance

• Better Thermal Conductivity for Higher Power

Dissipation

• Lead‑free

* For more information see the Surface Mount Schottky Reliability

Data Sheet.

PLx

SOT-363 Package Lead Code Identiﬁcation (top view)

SERIES

SINGLE

1 2

COMMON

CATHODE

COMMON

ANODE

1 2

BRIDGE

QUAD

UNCONNECTED

TRIO

RING

QUAD

1 2 3

6 5 4

1 2 3

6 5 4

1 2 3

6 5 4

HIGH ISOLATION

UNCONNECTED PAIR

1 2 3

6 5 4

COMMON

CATHODE

UNCONNECTED

PAIR

COMMON

ANODE

SERIES

SINGLE

1 2

3 4

1 2

SOT-23/SOT-143 DC Electrical Speciﬁcations, TC = +25°C, Single Diode

Part Package Typical

Number Marking Lead Forward Voltage Capacitance

HSMS- Code Code Conﬁguration VF (mV) CT (pF)

2860 T0 0 Single 250 Min. 350 Max. 0.30

2862 T2 2 Series Pair[1,2]

2863 T3 3 Common Anode[1,2]

2864 T4 4 Common Cathode[1,2]

2865 T5 5 Unconnected Pair [1,2]

Test Conditions IF = 1.0 mA VR = 0 V, f = 1 MHz

Notes:

1. ∆VF for diodes in pairs is 15.0 mV maximum at 1.0 mA.

2. ∆CT for diodes in pairs is 0.05 pF maximum at –0.5V.

SOT-323/SOT-363 DC Electrical Speciﬁcations, TC = +25°C, Single Diode

Part Package Typical

Number Marking Lead Forward Voltage Capacitance

HSMS- Code Code Conﬁguration VF (mV) CT (pF)

286B T0 B Single 250 Min. 350 Max. 0.25

286C T2 C Series Pair[1,2]

286E T3 E Common Anode[1,2]

286F T4 F Common Cathode[1,2]

286K TK K High Isolation

Unconnected Pair

286L TL L Unconnected Trio

286P TP P Bridge Quad

286R ZZ R Ring Quad

Test Conditions IF = 1.0 mA VR = 0 V, f = 1 MHz

Notes:

1. ∆VF for diodes in pairs is 15.0 mV maximum at 1.0 mA.

2. ∆CT for diodes in pairs is 0.05 pF maximum at –0.5V.

RF Electrical Speciﬁcations, TC = +25°C, Single Diode

Part Typical Tangential Sensitivity Typical Voltage Sensitivity g Typical Video

Number TSS (dBm) @ f = (mV/µW) @ f = Resistance

HSMS- 915 MHz 2.45 GHz 5.8 GHz 915 MHz 2.45 GHz 5.8 GHz RV (KΩ)

2860 – 57 –56 –55 50 35 25 5.0

2862

2863

2864

2865

286B

286C

286E

286F

286K

286L

286P

286R

Test Video Bandwidth = 2 MHz Power in = –40 dBm Ib = 5 µA

Conditions Ib = 5 µA RL = 100 KΩ, Ib = 5 µA

Absolute Maximum Ratings, TC = +25°C, Single Diode

Symbol Parameter Unit Absolute Maximum[1]

SOT-23/143 SOT-323/363

PIV Peak Inverse Voltage V 4.0 4.0

TJ Junction Temperature °C 150 150

TSTG Storage Temperature °C ‑65 to 150 ‑65 to 150

TOP Operating Temperature °C ‑65 to 150 ‑65 to 150

θjc Thermal Resistance[2] °C/W 500 150

Notes:

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

device.

2. TC = +25°C, where TC is deﬁned to be the temperature at the package pins where contact is

made to the circuit board.

ESD Machine Model (Class A)

ESD Human Body Model (Class 0)

Refer to Avago Application Note A004R:

Electro-

static Discharge Damage and Control.

Attention:

Observe precautions for

handling electrostatic

sensitive devices.

Equivalent Linear Circuit Model, Diode chip SPICE Parameters

Parameter Units Value

BV V 7.0

CJ0 pF 0.18

EG eV 0.69

IBV A 1 E ‑ 5

IS A 5 E ‑ 8

N 1.08

RS Ω 6.0

PB (VJ) V 0.65

PT (XTI) 2

M 0.5

Rj = 8.33 X 10-5 nT

Ib + Is

where

Ib = externally applied bias current in amps

Is = saturation current (see table of SPICE parameters)

T = temperature, °K

n = ideality factor (see table of SPICE parameters)

Note:

To effectively model the packaged HSMS-286x product,

please refer to Application Note AN1124.

RS = series resistance (see Table of SPICE parameters)

Cj = junction capacitance (see Table of SPICE parameters)

Typical Parameters, Single Diode

100

FORWARD VOLTAGE DIFFERENCE(mV)

VOLTAGE OUT (mV)

POWER IN (dBm)

0.05 0.15 0.200.10 0.25

FORWARD VOLTAGE (V)

.01

100

0.1 0.2 0.3 0.4 0. 70.6 0.8 0.90.5 1.0

FORWARD CURRENT (mA)

FORWARD VOLTAGE (V)

100

1000

10,000

–40 –30 –10 0–20 10 5

.1 1 1 0 100

OUTPUT VOLTAGE (mV)

BIAS CURRENT (µA)

TA = –55°C

TA = +25°C

TA = +85°C

IF (left scale)

VF (right scale)

Frequency = 2.45 GHz

Fixed-tuned FR4 circuit

RL = 100 KΩ

20 µA

5 µA

10 µA

Input Power =

–30 dBm @ 2.45 GHz

Data taken in fixed-tuned

FR4 circuit

RL = 100 KΩ

VOLTAGE OUT (mV)

-50

0.1

POWER IN (dBm)

-30 -2 0

10000

-40 0

100

-1 0

1000

RL = 100 KΩ

5.8 GHz

DIODES TESTED IN FIXED-TUNED

FR4 MICROSTRIP CIRCUITS.

915 MHz

2.45 GHz

VOLTAGE OUT (mV)

-50

0.3

POWER IN (dBm)

-30

-40

RL = 100 KΩ

2.45 GHz

915 MHz

5.8 GHz

DIODES TESTED IN FIXED-TUNED

FR4 MICROSTRIP CIRCUITS.

FORWARD CURRENT (mA)

Appli cations Information

Introduction

Avago’s HSMS‑286x family of Schottky detector diodes

has been developed speciﬁcally for low cost, high

volume designs in two kinds of applications. In small

signal detector applications (Pin < ‑20 dBm), this diode is

used with DC bias at frequencies above 1.5 GHz. At lower

frequencies, the zero bias HSMS‑285x family should be

considered.

In large signal power or gain control applications

(Pin > ‑20 dBm), this family is used without bias at

frequencies above 4 GHz. At lower frequencies, the

HSMS‑282x family is preferred.

Schottky Barrier Diode Characteristics

Stripped of its package, a Schottky barrier diode chip

consists of a metal‑semiconductor barrier formed by

deposition of a metal layer on a semiconductor. The most

common of several diﬀerent types, the passivated diode,

is shown in Figure 7, along with its equivalent circuit.

The Height of the Schottky Barrier

The current‑voltage character istic of a Schottky barrier

diode at room temperature is described by the following

equation:

HSMS-285A/6A fig 9

METAL

SCHOTTKY JUNCTION

PASSIVATION PASSIVATION

N-TYPE OR P-TYPE EPI LAYER

N-TYPE OR P-TYPE SILICON SUBSTRATE

CROSS-SECTION OF SCHOTTKY

BARRIER DIODE CHIP

EQUIVALENT

CIRCUIT

Figure 7. Schottky Diode Chip.

RS is the parasitic series resistance of the diode, the sum

of the bondwire and leadframe resistance, the resistance

of the bulk layer of silicon, etc. RF energy coupled into

RS is lost as heat —it does not contribute to the rectiﬁed

output of the diode. CJ is parasitic junction capaci tance

of the diode, controlled by the thickness of the epitaxial

layer and the diameter of the Schottky contact. Rj is the

junction resistance of the diode, a function of the total

current ﬂowing through it.

Figure 8. Equivalent Circuit of a Schottky Diode Chip.

RS is perhaps the easiest to measure accurately. The V‑I

curve is measured for the diode under forward bias, and

the slope of the curve is taken at some relatively high

value of current (such as 5 mA). This slope is converted

into a resistance Rd.

8.33 X 10 -5 n T

Rj = = R V - R s

IS + I b

0.026

= at 25°C

IS + I b

V - IR S

I = I S (exp ( ) - 1)

0.026

8.33 X 10 -5 n T

Rj = = R V - R s

IS + I b

0.026

= at 25°C

IS + I b

V - IR S

I = I S (exp ( ) - 1)

0.026

where

n = ideality factor (see table of SPICE parameters)

T = temperature in °K

IS = saturation current (see table of SPICE parameters)

Ib = externally applied bias current in amps

IS is a function of diode barrier height, and can range

from picoamps for high barrier diodes to as much as 5

µA for very low barrier diodes.

On a semi‑log plot (as shown in the Avago catalog) the

current graph will be a straight line with inverse slope

2.3 X 0.026 = 0.060 volts per cycle (until the eﬀect of RS is

seen in a curve that droops at high current). All Schottky

diode curves have the same slope, but not necessar‑

ily the same value of current for a given voltage. This is

deter mined by the saturation current, IS, and is related to

the barrier height of the diode.

Through the choice of p‑type or n‑type silicon, and the

selection of metal, one can tailor the characteristics of a

Schottky diode. Barrier height will be altered, and at the

same time CJ and RS will be changed. In general, very

low barrier height diodes (with high values of IS, suitable

for zero bias applica tions) are realized on p‑type silicon.

Such diodes suﬀer from higher values of RS than do

the n‑type. Thus, p‑type diodes are generally reserved

for small signal detector applications (where very high

values of RV swamp out high RS) and n‑type diodes are

used for mixer applications (where high L.O. drive levels

keep RV low) and DC biased detectors.

Measuring Diode Linear Parameters

The measurement of the many elements which make

up the equivalent circuit for a pack aged Schottky diode

is a complex task. Various techniques are used for each

element. The task begins with the elements of the diode

chip itself. (See Figure 8).

RV = R j + R S

0.026

RS = R d - If

For n‑type diodes with relatively low values of saturation

current, Cj is obtained by measuring the total capaci‑

tance (see AN1124). Rj, the junction resistance, is calcu‑

lated using the equation given above.

The characterization of the surface mount package is

too complex to describe here — linear equivalent circuits

can be found in AN1124.

Detector Circuits (small signal)

When DC bias is available, Schottky diode detector

circuits can be used to create low cost RF and

microwave receivers with a sensitivity of ‑55 dBm to

‑57 dBm.[1] Moreover, since external DC bias sets the

video impedance of such circuits, they display classic

square law response over a wide range of input power

levels[2,3]. These circuits can take a variety of forms, but

in the most simple case they appear as shown in Figure

9. This is the basic detector circuit used with the HSMS‑

286x family of diodes.

Output voltage can be virtually doubled and input

impedance (normally very high) can be halved through

the use of the voltage doubler circuit[4].

In the design of such detector circuits, the starting point

is the equivalent circuit of the diode. Of interest in the

design of the video portion of the circuit is the diode’s

video impedance — the other elements of the equiv‑

alent circuit disappear at all reasonable video frequen‑

cies. In general, the lower the diode’s video impedance,

the better the design.

The situation is somewhat more complicated in the

design of the RF impedance matching net work, which

includes the pack age inductance and capacitance

(which can be tuned out), the series resistance, the

junction capacitance and the video resistance. Of the

elements of the diode’s equiv alent circuit, the parasitics

are constants and the video resistance is a function of

the current ﬂowing through the diode.

[1] Avago Application Note 923, Schottky Barrier Diode Video

Detectors.

[2] Avago Application Note 986, Square Law and Linear Detection.

[3] Avago Application Note 956‑5, Dynamic Range Extension of Schottky

Detectors.

[4] Avago Application Note 956‑4, Schottky Diode Voltage Doubler.

[5] Avago Application Note 963, Impedance Matching Techniques for

Mixers and Detectors.

HSMS-285A/6A fig 12

VIDEO

OUT

Z-MATCH

NETWORK

DC BIAS

VIDEO

OUT

Z-MATCH

NETWORK

DC BIAS

Figure 9. Basic Detector Circuits.

HSMS-285A/6A fig 13

1 GHz

0.2 0.6 1

Figure 10. RF Impedance of the Diode.

RV = R j + R S

0.026

RS = R d - If

The sum of saturation current and bias current sets

the detection sensitivity, video resistance and input RF

impedance of the Schottky detector diode. Where bias

current is used, some tradeoﬀ in sensitivity and square

law dynamic range is seen, as shown in Figure 5 and

described in reference [3].

The most diﬃcult part of the design of a detector circuit

is the input impedance matching network. For very

broadband detectors, a shunt 60 Ω resistor will give good

input match, but at the expense of detection sensitivity.

When maximum sensitivity is required over a narrow

band of frequencies, a reactive matching network is

optimum. Such net works can be realized in either lumped

or distributed elements, depending upon frequency,

size constraints and cost limitations, but certain general

design principals exist for all types.[5] Design work begins

with the RF impedance of the HSMS‑286x series when

bias current is set to 3 µA. See Figure 10.

915 MHz Detector Circuit

Figure 11 illustrates a simple impedance matching network

for a 915 MHz detector.

The HSMS‑282x family is a better choice for 915 MHz ap‑

plications—the foregoing discussion of a design using

the HSMS‑286B is oﬀered only to illustrate a design

approach for technique.

HSMS-285A/6A fig 14

65nH

100 pF

VIDEO

OUT

INPUT

WIDTH = 0.050"

LENGTH = 0.065"

WIDTH = 0.015"

LENGTH = 0.600"

TRANSMISSION LINE

DIMENSIONS ARE FOR

MICROSTRIP ON

0.032" THICK FR-4.

HSMS-285A/6A fig 15

FREQUENCY (GHz): 0.9-0.93

HSMS-285A/6A fig 16

RETURN LOSS (dB)

0.9

-20

FREQUENCY (GHz)

0.915

-10

-15

0.93

-5

100 pF

VIDEO

OUT

INPUT

WIDTH = 0.017"

LENGTH = 0.436"

WIDTH = 0.078"

LENGTH = 0.165"

TRANSMISSION LINE

DIMENSIONS ARE FOR

MICROSTRIP ON

0.032" THICK FR-4.

0.030" PLATED THROUGH HOLE,

3 PLACES

0.094" THROUGH, 4 PLACES

FINISHED

BOARD

SIZE IS

1.00" X 1.00".

MATERIAL IS

1/32" FR-4

EPOXY/

FIBERGLASS,

1 OZ. COPPER

BOTH SIDES.

HSMS-2860 fig 15

Figure 11. 915 MHz Matching Network for the HSMS-286x Series at 3 µA Bias.

A 65 nH inductor rotates the impedance of the diode to

a point on the Smith Chart where a shunt inductor can

pull it up to the center. The short length of 0.065” wide

microstrip line is used to mount the lead of the diode’s

SOT‑323 package. A shorted shunt stub of length <λ/4

provides the necessary shunt inductance and simul‑

taneously provides the return circuit for the current

generated in the diode. The impedance of this circuit is

given in Figure 12.

Figure 12. Input Impedance.

The input match, expressed in terms of return loss, is

given in Figure 13.

Figure 13. Input Return Loss.

As can be seen, the band over which a good match is

achieved is more than adequate for 915 MHz RFID ap‑

plications.

Figure 14. 2.45 GHz Matching Network.

Figure 15. Physical Realization.

2.45 GHz Detector Circuit

At 2.45 GHz, the RF impedance is closer to the line of

constant susceptance which passes through the center

of the chart, resulting in a design which is realized

entirely in distributed elements — see Figure 14.

In order to save cost (at the expense of having a larger

circuit), an open circuit shunt stub could be substituted

for the chip capacitor. On the other hand, if space is at a

premium, the long series transmission line at the input

to the diode can be replaced with a lumped inductor. A

possible physical realization of such a network is shown

in Figure 15, a demo board is available from Avago.

CHIP CAPACITOR, 20 TO 100 pF

HSMS-2860

HSMS-285X fig 20 was 17

VIDEO OUTRF IN

Figure 16. Test Detector.

Two SMA connectors (E.F. Johnson 142‑0701‑631 or

equivalent), a high‑Q capacitor (ATC 100A101MCA50 or

equivalent), miscellaneous hardware and an HSMS‑286B

are added to create the test circuit shown in Figure 16.

The calculated input impedance for this network is

shown in Figure 17.

Figure 19. Input Impedance. Modiﬁed 2.45 GHz Circuit.

This does indeed result in a very good match at midband,

as shown in Figure 20.

HSMS-0005 fig 21 was 18

FREQUENCY (GHz): 2.3-2.6

HSMS-285X fig 22 was 19

RETURN LOSS (dB)

2.3

-20

FREQUENCY (GHz)

2.45

-10

-15

2.6

-5

HSMS-0005 fig 23 was 20

FREQUENCY (GHz): 2.3-2.6

2.45 GHz

HSMS-285X fig 24 was 21

RETURN LOSS (dB)

2.3

-20

FREQUENCY (GHz)

2.45

-10

-15

2.6

-5

Figure 17. Input Impedance, 3 µA Bias.

The corresponding input match is shown in Figure 18. As

was the case with the lower frequency design, bandwidth

is more than adequate for the intended RFID application.

Figure 18. Input Return Loss, 3 µA Bias.

A word of caution to the designer is in order. A glance

at Figure 17 will reveal the fact that the circuit does

not provide the optimum impedance to the diode at

2.45 GHz. The temptation will be to adjust the circuit

elements to achieve an ideal single frequency match, as

illustrated in Figure 19.

Figure 20. Input Return Loss. Modiﬁed 2.45 GHz Circuit.

However, bandwidth is narrower and the designer runs

the risk of a shift in the mid band frequency of his circuit

if there is any small deviation in circuit board or diode

character istics due to lot‑to‑lot variation or change in

temper‑ature. The matching technique illustrated in

Figure 17 is much less sensitive to changes in diode and

circuit board processing.

5.8 GHz Detector Circuit

A possible design for a 5.8 GHz detector is given in Figure

21.

20 pF

VIDEO

OUT

INPUT

WIDTH = 0.016"

LENGTH = 0.037"

WIDTH = 0.045"

LENGTH = 0.073"

TRANSMISSION LINE

DIMENSIONS ARE FOR

MICROSTRIP ON

0.032" THICK FR-4.

Figure 21. 5.8 GHz Matching Network for the HSMS-286x Series at 3 µA Bias.

As was the case at 2.45 GHz, the circuit is entirely dis‑

tributed element, both low cost and compact. Input

impedance for this network is given in Figure 22.

Such a circuit oﬀers several advantages. First the voltage

outputs of two diodes are added in series, increasing

the overall value of voltage sensitivity for the network

(compared to a single diode detector). Second, the RF

impedances of the two diodes are added in parallel,

making the job of reactive matching a bit easier. Such a

circuit can easily be realized using the two series diodes

in the HSMS‑286C.

The “Virtual Battery”

The voltage doubler can be used as a virtual battery,

to provide power for the operation of an I.C. or a tran‑

sistor oscillator in a tag. Illuminated by the CW signal

from a reader or inter rogator, the Schottky circuit will

produce power suﬃcient to operate an I.C. or to charge

up a capacitor for a burst transmis sion from an oscilla‑

tor. Where such virtual batteries are employed, the bulk,

cost, and limited lifetime of a battery are eliminated.

Temperature Compensation

The compression of the detector’s transfer curve is

beyond the scope of this data sheet, but some general

comments can be made. As was given earlier, the diode’s

video resistance is given by

8.33 x 10‑5 nT

RV =

IS + Ib

where T is the diode’s temperature in °K.

As can be seen, temperature has a strong eﬀect upon RV,

and this will in turn aﬀect video bandwidth and input

RF impedance. A glance at Figure 6 suggests that the

proper choice of bias current in the HSMS‑286x series

can minimize variation over temperature.

The detector circuits described earlier were tested

over temperature. The 915 MHz voltage doubler using

the HSMS‑286C series produced the output voltages

as shown in Figure 25. The use of 3 µA of bias resulted

in the highest voltage sensitivity, but at the cost of a

wide variation over temperature. Dropping the bias to

1 µA produced a detector with much less temperature

variation.

A similar experiment was conducted with the HSMS‑

286B series in the 5.8 GHz detector. Once again, reducing

the bias to some level under 3 µA stabilized the output

of the detector over a wide temperature range.

It should be noted that curves such as those given in

Figures 25 and 26 are highly dependent upon the exact

design of the input impedance matching network. The

designer will have to experiment with bias current using

his speciﬁc design.

HSMS-0005 fig 26 was 23

FREQUENCY (GHz): 5.6-6.0

HSMS-285X fig 27 was 24

RETURN LOSS (dB)

5.6

-20

FREQUENCY (GHz)

5.8

-10

-15

6.0

-5

5.9

5.7

HSMS-285X fig 11 was 7

VIDEO OUT

Z-MATCH

NETWORK

RF IN

Figure 22. Input Impedance.

Input return loss, shown in Figure 23, exhibits wideband

match.

Figure 23. Input Return Loss.

Voltage Doublers

To this point, we have restricted our discus sion to

single diode detectors. A glance at Figure 9, however,

will lead to the suggestion that the two types of single

diode detectors be combined into a two diode voltage

doubler[4] (known also as a full wave rectiﬁer). Such a

detector is shown in Figure 24.

Figure 24. Voltage Doubler Circuit.

Figure 25. Output Voltage vs. Temperature and Bias Current

in the 915 MHz Voltage Doubler using the HSMS-286C.

in a single package, such as the SOT‑143 HSMS‑2865 as

shown in Figure 29.

In high power diﬀerential detectors, RF coupling from

the detector diode to the reference diode produces a

rectiﬁed voltage in the latter, resulting in errors.

Isolation between the two diodes can be obtained

by using the HSMS‑286K diode with leads 2 and 5

grounded. The diﬀerence between this product and the

conventional HSMS‑2865 can be seen in Figure 29.

-55 -35 -15 5 8545 65

OUTPUT VOLTAGE (mV)

TEMPERATURE (°C)

120

100

INPUT POWER = –30 dBm

3.0 µA

1.0 µA

10 µA

0.5 µA

OUTPUT VOLTAGE (mV)

TEMPERATURE (

INPUT POWER = –30 dBm

3.0 µA

10 µA

1.0 µA

0.5 µA

-55 -35 -15 5 8545 6525

matching

network

differential

amplifier

bias

to differential

amplifier

detector

diode

reference diode

HSMS-2865

Figure 26. Output Voltage vs. Temperature and Bias Current

in the 5.80 GHz Voltage Detector using the HSMS-286B Schottky.

Six Lead Circuits

The diﬀerential detector is often used to provide temper‑

ature compensation for a Schottky detector, as shown in

Figures 27 and 28.

Figure 27. Diﬀerential Detector.

Figure 28. Conventional Diﬀerential Detector.

These circuits depend upon the use of two diodes

having matched Vf characteristics over all operating

temperatures. This is best achieved by using two diodes

HSMS-2865

SOT-143

HSMS-286K

SOT-363

3 4 6 5 4

11 2 2 3

to differential

amplifier

detector

diode

reference diode

HSMS-286K

-35 -25 -15 -5 155

37 dB

47 dB

OUTPUT VOLTAGE (mV)

INPUT POWER (dBm)

0.5

1000

100

5000

Frequency = 900 MHz

HSMS-2825

ref. diode

RF diode

Vout

Square law

response

HSMS-282K

ref. diode

Figure 29. Comparing Two Diodes.

The HSMS‑286K, with leads 2 and 5 grounded, oﬀers

some isolation from RF coupling between the diodes.

This product is used in a diﬀerential detector as shown

in Figure 30.

Figure 30. High Isolation Diﬀerential Detector.

In order to achieve the maximum isolation, the designer

must take care to minimize the distance from leads 2

and 5 and their respective ground via holes.

Tests were run on the HSMS‑282K and the conventional

HSMS‑2825 pair, which compare with each other in the

same way as the HSMS‑2865 and HSMS‑286K, with the

results shown in Figure 31.

Figure 31. Comparing HSMS-282K with HSMS-2825.

The line marked “RF diode, Vout” is the transfer curve for

the detector diode— both the HSMS‑2825 and the HSMS‑

282K exhibited the same output voltage. The data were

taken over the 50 dB dynamic range shown. To the right

is the output voltage (transfer) curve for the reference

diode of the HSMS‑2825, showing 37 dB of isolation. To

the right of that is the output voltage due to RF leakage

for the reference diode of the HSMS‑282K, demonstrating

10 dB higher isolation than the conventional part.

Such diﬀerential detector circuits generally use single

diode detectors, either series or shunt mounted diodes.

The voltage doubler oﬀers the advantage of twice

the output voltage for a given input power. The two

concepts can be combined into the diﬀerential voltage

doubler, as shown in Figure 32.

PRF = RF power dissipated

Note that θjc, the thermal resistance from diode junction

to the foot of the leads, is the sum of two component

resistances,

matching

network

bias

differential

amplifier

Figure 32. Diﬀerential Voltage Doubler, HSMS-286P.

Here, all four diodes of the HSMS‑286P are matched in

their Vf characteristics, because they came from adjacent

sites on the wafer. A similar circuit can be realized using

the HSMS‑286R ring quad.

Other conﬁgurations of six lead Schottky products can

be used to solve circuit design problems while saving

space and cost.

Thermal Considerations

The obvious advantage of the SOT‑363 over the SOT‑

143 is combination of smaller size and two extra leads.

However, the copper leadframe in the SOT‑323 and SOT‑

363 has a thermal conductivity four times higher than

the Alloy 42 leadframe of the SOT‑23 and SOT‑143, which

enables it to dissipate more power.

The maximum junction temperature for these three

families of Schottky diodes is 150°C under all operating

conditions. The following equation, equation 1, applies

to the thermal analysis of diodes:

11600 (V f- I f R s)

If = I S e - 1

Equation (3).

2 1 1

n - 4060 (T- 298)

Is = I 0 ( T ) e

298

Equation (4).

Tj = (V fIf + P RF )θjc + T aEquation (1).

θjc = θpkg + θchip Equation (2).

11600 (V f- I f R s)

If = I S e - 1

Equation (3).

2 1 1

n - 4060 (T- 298)

Is = I 0 ( T ) e

298

Equation (4).

Tj = (V fIf + P RF )θjc + T aEquation (1).

θjc = θpkg + θchip Equation (2).

11600 (V f- I f R s)

If = I S e - 1

Equation (3).

2 1 1

n - 4060 (T- 298)

Is = I 0 ( T ) e

298

Equation (4).

Tj = (V fIf + P RF )θjc + T aEquation (1).

θjc = θpkg + θchip Equation (2).

11600 (V f- I f R s)

If = I S e - 1

Equation (3).

2 1 1

n - 4060 (T- 298)

Is = I 0 ( T ) e

298

Equation (4).

Tj = (V fIf + P RF )θjc + T aEquation (1).

θjc = θpkg + θchip Equation (2).

where

Tj = junction temperature

Ta = diode case temperature

θjc = thermal resistance

VfIf = DC power dissipated

Package thermal resistance for the SOT‑323 and SOT‑363

package is approximately 100°C/W, and the chip thermal

resistance for these three families of diodes is approxi‑

mately 40°C/W. The designer will have to add in the

thermal resistance from diode case to ambient — a poor

choice of circuit board material or heat sink design can

make this number very high.

Equation (1) would be straightforward to solve but

for the fact that diode forward voltage is a function of

temperature as well as forward current. The equation,

equation 3, for Vf is:

where

n = ideality factor

T = temperature in °K

Rs = diode series resistance

and IS (diode saturation current) is given by

Equations (1) and (3) are solved simultaneously to obtain

the value of junction temperature for given values of

diode case temperature, DC power dissipation and RF

power dissipation.

Diode Burnout

Any Schottky junction, be it an RF diode or the gate of

a MESFET, is relatively delicate and can be burned out

with excessive RF power. Many crystal video receivers

used in RFID (tag) applications ﬁnd themselves in poorly

controlled environments where high power sources may

be present. Examples are the areas around airport and

FAA radars, nearby ham radio operators, the vicinity of

a broadcast band transmitter, etc. In such environments,

the Schottky diodes of the receiver can be protected by

a device known as a limiter diode.[6] Formerly available

only in radar warning receivers and other high cost

electronic warfare applications, these diodes have been

adapted to commercial and consumer circuits.

Avago oﬀers a com plete line of surface mountable PIN

limiter diodes. Most notably, our HSMP‑4820 (SOT‑23)

or HSMP‑482B (SOT‑323) can act as a very fast (nano‑

second) power‑sensitive switch when placed between

the antenna and the Schottky diode, shorting out the

RF circuit temporarily and reﬂecting the excessive RF

energy back out the antenna.

Figure 34. Recommended PCB Pad Layout for Avago’s SC70 6L/SOT-363

Products.

[6] Avago Application Note 1050, Low Cost, Surface Mount Power Limiters.

0.026

0.039

0.079

0.022

Dimensions in inches

0.026

0.075

0.016

0.035

Figure 33. Recommended PCB Pad Layout for Avago’s SC70 3L/SOT-323

Products.

A recommended PCB pad layout for the miniature

SOT‑363 (SC‑70 6 lead) package is shown in Figure 34

(dimensions are in inches). This layout provides ample

allowance for package placement by automated

assembly equipment without adding parasitics that could

impair the performance.

Assembly Instructions

SOT-323 PCB Footprint

A recommended PCB pad layout for the miniature SOT‑

323 (SC‑70) package is shown in Figure 33 (dimensions

are in inches).

Figure 35. Surface Mount Assembly Proﬁle.

SMT Assembly

Reliable assembly of surface mount components is a

complex process that involves many material, process,

and equipment factors, including: method of heating

(e.g., IR or vapor phase reﬂow, wave soldering, etc.)

circuit board material, conductor thickness and pattern,

type of solder alloy, and the thermal conductivity and

thermal mass of components. Components with a low

mass, such as the SOT packages, will reach solder reﬂow

temperatures faster than those with a greater mass.

Avago’s diodes have been qualiﬁed to the time‑tem‑

perature proﬁle shown in Figure 35. This proﬁle is repre‑

sentative of an IR reﬂow type of surface mount assembly

process.

After ramping up from room temperature, the circuit

board with components attached to it (held in place

with solder paste) passes through one or more preheat

Time

Temperature

t 25° C to Peak

Ramp-up

min

Ramp-down

Preheat

Critical Zone

to Tp

max

Lead-Free Reﬂow Proﬁle Recommendation (IPC/JEDEC J-STD-020C)

Reﬂow Parameter Lead-Free Assembly

Average ramp‑up rate (Liquidus Temperature (TS(max) to Peak) 3°C/ second max

Preheat Temperature Min (TS(min)) 150°C

Temperature Max (TS(max)) 200°C

Time (min to max) (tS) 60‑180 seconds

Ts(max) to TL Ramp‑up Rate 3°C/second max

Time maintained above: Temperature (TL) 217°C

Time (tL) 60‑150 seconds

Peak Temperature (TP) 260 +0/‑5°C

Time within 5 °C of actual Peak temperature (tP) 20‑40 seconds

Ramp‑down Rate 6°C/second max

Time 25 °C to Peak Temperature 8 minutes max

Note 1: All temperatures refer to topside of the package, measured on the package body surface

zones. The preheat zones increase the temperature of

the board and components to prevent thermal shock

and begin evaporating solvents from the solder paste.

The reﬂow zone brieﬂy elevates the temperature suﬃ‑

ciently to produce a reﬂow of the solder.

The rates of change of temperature for the ramp‑up and

cool‑down zones are chosen to be low enough to not

cause deformation of the board or damage to compo‑

nents due to thermal shock. The maximum temperature

in the reﬂow zone (TMAX) should not exceed 260°C.

These parameters are typical for a surface mount assembly

process for Avago diodes. As a general guideline, the circuit

board and components should be exposed only to the

minimum temperatures and times necessary to achieve a

uniform reﬂow of solder.

Package Dimensions

Outline 23 (SOT-23)

Outline 143 (SOT-143) Outline SOT-363 (SC-70 6 Lead)

Outline SOT-323 (SC-70 3 Lead)

EXXX

Notes:

XXX-package marking

Drawings are not to scale

DIMENSIONS (mm)

MIN.

0.79

0.013

0.36

0.76

0.086

2.80

1.20

0.89

1.78

0.45

2.10

0.45

MAX.

1.097

0.10

0.54

0.92

0.152

3.06

1.40

1.02

2.04

0.60

2.65

0.69

SYMBOL

EXXX

Notes:

XXX-package marking

Drawings are not to scale

DIMENSIONS (mm)

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

SYMBOL

EXXX

Notes:

XXX-package marking

Drawings are not to scale

DIMENSIONS (mm)

MIN.

0.80

0.00

0.15

0.08

1.80

1.10

1.80

0.26

MAX.

1.00

0.10

0.40

0.25

2.25

1.40

2.40

0.46

SYMBOL

1.30 typical

0.65 typical

DIMENSIONS (mm)

MIN.

1.15

1.80

0.80

0.00

0.15

0.08

0.10

MAX.

1.35

2.25

2.40

1.10

1.00

0.10

0.30

0.25

0.46

SYMBOL

0.650 BCS

Device Orientation

USER

FEED

DIRECTION

COVER TAPE

CARRIER

TAPE

REEL

For Outline SOT-143

For Outlines SOT-23, -323

Note: "AB" represents package marking code.

"C" represents date code.

END VIE

8 mm

4 mm

TOP VIEW

ABC ABC ABC ABC

END VIE

8 mm

4 mm

TOP VIEW

Note: "AB" represents package marking code.

"C" represents date code.

ABC ABC ABC ABC

For Outline SOT-363

Note: "AB" represents package marking code.

"C" re

resents date code.

END VIE

8 mm

4 mm

TOP VIEW

ABC ABC ABC ABC

Tape Dimensions and Product Orientation

For Outline SOT-23

9° MAX

Ko 8° MAX

13.5° MAX

DESCRIPTION SYMBOL SIZE (mm) SIZE (INCHES)

LENGTH

WIDTH

DEPTH

PITCH

BOTTOM HOLE DIAMETER

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

CAVITY

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

PERFORATION

WIDTH

THICKNESS

8.00 + 0.30 – 0.10

0.229 ± 0.013

0.315 + 0.012 – 0.004

0.009 ± 0.0005

CARRIER TAPE

CAVITY TO PERFORATION

(WIDTH DIRECTION)

CAVITY TO PERFORATION

(LENGTH DIRECTION)

3.50 ± 0.05

2.00 ± 0.05

0.138 ± 0.002

0.079 ± 0.002

DISTANCE

BETWEEN

CENTERLINE

For Outline SOT-143

DESCRIPTION SYMBOL SIZE (mm) SIZE (INCHES)

LENGTH

WIDTH

DEPTH

PITCH

BOTTOM HOLE DIAMETER

3.19 ± 0.10

2.80 ± 0.10

1.31 ± 0.10

4.00 ± 0.10

1.00 + 0.25

0.126 ± 0.004

0.110 ± 0.004

0.052 ± 0.004

0.157 ± 0.004

0.039 + 0.010

CAVITY

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

PERFORATION

WIDTH

THICKNESS

8.00 + 0.30 – 0.10

0.254 ± 0.013

0.315+ 0.012 – 0.004

0.0100 ± 0.0005

CARRIER TAPE

CAVITY TO PERFORATION

(WIDTH DIRECTION)

CAVITY TO PERFORATION

(LENGTH DIRECTION)

3.50 ± 0.05

2.00 ± 0.05

0.138 ± 0.002

0.079 ± 0.002

DISTANCE

9° MAX 9° MAX

Tape Dimensions and Product Orientation

For Outlines SOT-323, -363

(CARRIER TAPE THICKNESS) T

(COVER TAPE THICKNESS)

DESCRIPTION SYMBOL SIZE (mm) SIZE (INCHES)

LENGTH

WIDTH

DEPTH

PITCH

BOTTOM HOLE DIAMETER

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

CAVITY

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

PERFORATION

WIDTH

THICKNESS

8.00 ± 0.30

0.254 ± 0.02

0.315 ± 0.012

0.0100 ± 0.0008

CARRIER TAPE

CAVITY TO PERFORATION

(WIDTH DIRECTION)

CAVITY TO PERFORATION

(LENGTH DIRECTION)

3.50 ± 0.05

2.00 ± 0.05

0.138 ± 0.002

0.079 ± 0.002

DISTANCE

FOR SOT-323 (SC70-3 LEAD) An 8°C MAX

FOR SOT-363 (SC70-6 LEAD) 10°C MAX

ANGLE

WIDTH

TAPE THICKNESS

5.4 ± 0.10

0.062 ± 0.001

0.205 ± 0.004

0.0025 ± 0.00004

COVER TAPE

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 in the United States and other countries.

Obsoletes 5989-4023EN

AV02-1388EN - August 26, 2009

Part Number Ordering Information

Part Number No. of Devices Container

HSMS‑286x‑TR2G 10000 13” Reel

HSMS‑286x‑TR1G 3000 7” Reel

HSMS‑286x‑BLKG 100 antistatic bag

where x = 0, 2, 3, 4, 5, B, C, E, F, K, L, P or R for HSMS‑286x.