HLMP-P202-F00 [AVAGO]

Single Color LED, High Efficiency Red, Untinted Diffused, 1.78mm;


型号：	HLMP-P202-F00
厂家：	AVAGO TECHNOLOGIES LIMITED
描述：	Single Color LED, High Efficiency Red, Untinted Diffused, 1.78mm
文件：	总17页 (文件大小：464K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

Subminiature LEDLamps

TechnicalData

HLMP -P xxx Ser ies

HLMP -Qxxx Ser ies

HLMP -6xxx Ser ies

HLMP -70xx Ser ies

F ea tu r es

Dom e P a ck a ges

• Su b m in ia t u r e F la t Top

P a ck a ge

The HLMP-6xxx Series dome

lamps for use as indicators use

a tinted, diffused lens to

provide a wide viewing angle

with a high on-off contrast

ratio. High brightness lamps

use an untinted, nondiffused

lens toprovide a high luminous

intensity within a narrow

radiation pattern.

Ideal for Backlighting and

Light Piping Applications

• Su b m in ia t u r e Dom e

P a ck a ge

Diffused Dome for Wide

Viewing Angle

Nondiffused Dome for High

Brightness

• TTL a n d LSTTL

Com p a t ib le 5 Volt R esist or

La m p s

R esist or La m p s

The HLMP-6xxx Series 5 volt

subminiature lamps with built

in current limiting resistors are

for use in applications where

space is at a premium.

available. These include special

surface mount lead configura-

tions, gull wing, yoke lead or Z-

bend. Right angle lead bends at

2.54 mm (0.100 inch) and

5.08 mm (0.200 inch) center

spacing are available for

through hole mounting. For

more information refer to

Standard SMT and Through

Hole Lead Bend Options for

Subminiature LED Lamps data

sheet.

• Ava ila b le in Six Color s

• Id ea l for Sp a ce Lim it ed

Ap p lica t ion s

• Axia l Lea d s

Lea d Con figu r a t ion s

• Ava ila b le w it h Lea d

Con figu r a t ion s for Su r fa ce

Mou n t a n d Th r ou gh H ole

P C Boa r d Mou n t in g

All of these devices are made by

encapsulating LED chips on

axial lead frames to form

molded epoxy subminiature

lamp packages. A variety of

package configuration options is

Descr ip tion

F la t Top P a ck a ge

The HLMP-Pxxx Series flat top

lamps use an untinted, non-

diffused, truncated lens to

provide a wide radiation

pattern that is necessary for

use in backlighting

applications. The flat top lamps

are also ideal for use as

emitters in light pipe

applications.

Device Selection Gu id e

P a r t Nu m ber : HLMP -xxxx

DH AS

H igh

Device

St a n d a r d AlGa As E fficien cy

P er f. E m er a ld

Ou t lin e

R ed

Or a n ge Yellow Gr een

Gr een

Device Descr ip t ion ^[1]Dr a w in g

P105

P205

P405

P402

Q400

P305

P505

P502

P605

Untinted, Nondiffused,

Flat Top

P102

P202

P302

Untinted, Diffused,

Flat Top

6000

Q100

Q105

6300

6305

6400

6405

6500

6505

Q600

Tinted, Diffused

Untinted, Nondiffused,

High Brightness

Q150

Q155

7000

7019

7040

Tinted, Diffused, Low

Current

Nondiffused, Low

Current

6600

6620

6700

6720

6800

6820

Tinted, Diffused,

Resistor, 5 V, 10 mA

Diffused, Resistor, 5 V,

4 mA

Or d er in g In for m a tion

HLMX-XXXX-X X X X X

4 x 4

Prod.

Part

Packaging

Option

Number

Min. Iv

Bin

Color Bin

Selection

Max. Iv

Bin

P a ck a ge Dim en sion s

(A) F la t Top La m p s

2.21(0.087)

1.96(0.077)

0.50 (0.020) REF.

1.40 (0.055)

1.65 (0.065)

1.14 (0.045)

1.40 (0.055)

0.63

0.38

(0.025)

(0.015)

11.68(0.460)

10.67(0.420)

BOTH SIDES

CATHODE

2.44(0.096)

1.88(0.074)

0.46 (0.018)

0.56 (0.022)

ANODE

CATHODE

STRIPE

0.79 (0.031) MAX.

0.18 (0.007)

0.23 (0.009)

1.65(0.065)

DIA.

2.08(0.082)

2.34(0.092)

1.91(0.075)

0.25 (0.010) MAX.*

NOTE 2

0.20 (0.008) MAX.

NOTES:

1. ALL DIMENSIONS ARE IN MILLIMETRES (INCHES).

2. PROTRUDING SUPPORT TAB IS CONNECTED TO CATHODE LEAD.

* REFER TO FIGURE 1 FOR DESIGN CONCERNS.

P a ck a ge Dim en sion s (con t.)

(B) Diffu sed an d Non diffu sed

2.21(0.087)

1.96(0.077)

0.76 (0.030)

0.18 (0.007)

0.23 (0.009)

0.89 (0.035)

0.50 (0.020) REF.

0.94 (0.037)

1.24 (0.049)

2.03 (0.080)

1.78 (0.070)

11.68(0.460)

10.67(0.420)

BOTH SIDES

CATHODE

2.92 (0.115)

MAX.

0.46 (0.018)

0.56 (0.022)

ANODE

0.63 (0.025)

0.38 (0.015)

0.79 (0.031)

0.53 (0.021)

1.65(0.065)

DIA.

CATHODE

STRIPE

1.91(0.075)

0.25 (0.010) MAX.*

NOTE 2

2.08(0.082)

2.34(0.092)

0.20 (0.008) MAX.

NOTES:

1. ALL DIMENSIONS ARE IN MILLIMETRES (INCHES).

2. PROTRUDING SUPPORT TAB IS CONNECTED TO CATHODE LEAD.

* REFER TO FIGURE 1 FOR DESIGN CONCERNS.

CATHODE

TAB

NO. ANODE DOWN.

YES. CATHODE DOWN.

F igu r e 1. P r op er R igh t An gle Mou n t in g t o a P C Boa r d t o P r even t P r ot r u d in g Ca t h od e Ta b fr om

Sh or t in g t o An od e Con n ect ion .

Absolu te Ma xim u m Ra tin gs a t T_A= 25°C

DH AS

H igh

St a n d a r d AlGa As

E ff.

R ed

P er f. E m er a ld

P a r a m et er

DC Forward Current^[1]

Peak Forward Current^[2]

R ed

Or a n ge Yellow Gr een

Gr een

Un it s

1000

300

DC Forward Voltage

(Resistor Lamps Only)

Reverse Voltage (I_R= 100 µA)

Transient Forward Current^[3]

2000

500

(10 µs Pulse)

Operating Temperature Range:

Non-Resistor Lamps

-55 to

+100

-40 to

+100

-55 to +100

-40 to +85

-40 to

+100

-20 to

+100

°C

Resistor Lamps

-20 to

+85

Storage Temperature Range

-55 to +100

For Thru Hole Devices

260°C for 5 Seconds

Wave Soldering Temperature

[1.6 mm (0.063 in.) from body]

For Surface Mount Devices:

Convective IR

235°C for 90 Seconds

215°C for 3 Minutes

Vapor Phase

Not es:

1. See Figure 5 for current derating vs. ambient temperature. Derating is not applicable to resistor lamps.

2. Refer to Figure 6 showing Max. Tolerable Peak Current vs. Pulse Duration to establish pulsed operating conditions.

3. The transient peak current is the maximum non-recurring peak current the device can withstand without failure. Do not

operate these lamps at this high current.

Electr ica l/Op tica l Ch a r a cter istics, T_A= 25°C

St a n d a r d R ed

Device

H LMP -

P a r a m et er

Sym b ol Min . Typ . Ma x. Un it s

Test Con d it ion s

I_F= 10 mA

6000-E00xx Luminous Intensity^[1]

I_v

0.5

1.3

1.4

5.0

1.2

3.2

mcd

6000-G00xx

Forward Voltage

V_F

V_R

1.6

2.0

I_F= 10 mA

All

Reverse Breakdown

Voltage

12.0

I_R= 100 µA

Included Angle Between

Half Intensity Points^[2]

2θ¹/2

Deg.

Peak Wavelength

λ_PEAK

λ_d

655

640

Dominant Wavelength^[3]

Spectral Line Half Width ∆λ_1/2

All

Speed of Response

Capacitance

τ_s

100

170

V_F= 0; f = 1 MHz

Thermal Resistance

Rθ_{J -PIN}

°C/W J unction-to-Cathode

Lead

Luminous Efficacy^[4]

η_v

lm/W

DH AS AlGa As R ed

Device

H LMP -

P a r a m et er

Sym b ol Min . Typ . Ma x. Un it s

Test Con d it ion s

P102-F00xx

P105-L00xx

Q100-N00xx

1.0

8.6

20.0

30.0

I_F= 20 mA

I_F= 1 mA

22.0 45.0

Q105-P00xx Luminous Intensity

Q150-F00xx

I_v

1.0

200

1.8

mcd

Q155-F00xx

4.0

Q100

Q150/Q155

All

Forward Voltage

V_F

V_R

1.8

2.2

1.8

I_F= 20 mA

I_F= 1 mA

1.6

Reverse Breakdown

Voltage

5.0

15.0

I_R= 100 µA

P105

125

Q100/Q150 Included Angle Between

2θ /2

Deg.

Half Intensity Points^[2]

Q105/Q155

645

637

Peak Wavelength

λ_PEAK

λ_d

Measured at Peak

Exponential Time

Dominant Wavelength^[3]

Spectral Line Half Width

∆λ_1/2

τ_s

All

Speed of Response

Constant; e^-t/τ

Capacitance

V_F= 0; f = 1 MHz

Thermal Resistance

Rθ_{J -PIN}

170

°C/W J unction-to

Cathode Lead

Luminous Efficacy^[4]

η_v

lm/W

H igh E fficien cy R ed

Device

H LMP -

P a r a m et er

Sym b ol Min . Typ . Ma x. Un it s

Test Con d it ion s

P202-F00xx

1.0

5.0

8.0

P205-F00xx

6300-F00xx

10.0

I_F= 10 mA

6305-L00xx

10.0 40.0

7000-D00xx Luminous Intensity^[1]

I_v

0.4

1.3

0.8

1.5

1.0

5.0

2.0

1.8

mcd

I_F= 2 mA

6600-G00xx

V_F= 5.0 Volts

6620-F00xx

All

Forward Voltage

V_F

3.0

I_F= 10 mA

(Nonresistor Lamps)

6600

9.6

13.0

5.0

ForwardCurrent

(Resistor Lamps)

I_F

V_F= 5.0 V

6620

All

3.5

Reverse Breakdown

Voltage

V_R

5.0

30.0

I_R= 100 µA

P205

6305

125

Included Angle Between

Half Intensity Points^[2]

2θ¹/2

Deg.

All

Diffused

Peak Wavelength

λ_PEAK

λ_d

635

626

Measured at Peak

V_F= 0; f = 1 MHz

Dominant Wavelength^[3]

Spectral Line Half Width ∆λ_1/2

All

Speed of Response

Capacitance

τ_s

Thermal Resistance

Rθ_{J -PIN}

170

°C/W J unction-to-Cathode

Lead

Luminous Efficacy^[4]

η_v

145

lm/W

Or a n ge

Device

H LMP -

P a r a m et er

Sym b ol Min . Typ . Ma x. Un it s

Test Con d it ion s

P402-F00xx

1.0

1.5

5.0

4.0

P405-F00xx Luminous Intensity

Q400-F00xx

I_v

mcd

I_F= 10 mA

Forward Voltage

V_F

V_R

1.9

30.0

3.0

I_F= 10 mA

All

Reverse Breakdown

Voltage

I_R= 100 µA

P405

Q400

Included Angle Between

Half Intensity Points^[2]

125

2θ /2

Deg.

600

602

Peak Wavelength

λ_PEAK

λ_d

Dominant Wavelength^[3]

Measured at Peak

V_F= 0; f = 1 MHz

Spectral Line Half Width ∆λ_1/2

All

Speed of Response

Capacitance

τ_s

260

Thermal Resistance

Rθ_{J -PIN}

170

°C/W J unction-to-Cathode

Lead

Luminous Efficacy^[4]

η_v

380

lm/W

Yellow

Device

H LMP -

P a r a m et er

Sym b ol Min . Typ . Ma x. Un it s

Test Con d it ion s

P302-F00xx

P305-F00xx

6400-F00xx

1.0

3.6

0.4

1.4

0.9

3.0

4.0

9.0

I_F= 10 mA

6405-J 00xx Luminous Intensity^[1]

I_v

mcd

7019-D00xx

0.6

5.0

2.0

I_F= 2 mA

6700-G00xx

V_F= 5.0 Volts

6720-F00xx

All

Forward Voltage

(Nonresistor Lamps)

V_F

2.0

9.6

2.4

I_F= 10 mA

V_F= 5.0 V

6700

13.0

5.0

Forward Current

(Resistor Lamps)

I_F

6720

All

3.5

Reverse Breakdown

Voltage

V_R

5.0

50.0

P305

6405

125

Included Angle Between

Half Intensity Points^[2]

2θ /2

Deg.

All

Diffused

Peak Wavelength

Dominant Wavelength^[3]

λ_PEAK

λ_d

583

585

Measured at Peak

V_F= 0; f = 1 MHz

Spectral Line Half Width ∆λ_1/2

All

Speed of Response

Capacitance

τ_s

Thermal Resistance

Rθ_{J -PIN}

170

°C/W J unction-to-Cathode

Lead

Luminous Efficacy^[4]

η_v

500

lm/W

H igh P er for m a n ce Gr een

Device

H LMP -

P a r a m et er

Sym b ol Min . Typ . Ma x. Un it s

Test Con d it ion s

P502-F00xx

1.0

1.6

1.0

3.0

6.3

7.0

P505-G00xx

6500-F00xx

I_F= 10 mA

6505-L00xx

10.0 40.0

7040-D00xx Luminous Intensity^[1]

I_v

0.4

1.6

0.8

0.6

5.0

2.0

2.1

mcd

I_F= 2 mA

6800-G00xx

V_F= 5.0 Volts

6820-F00xx

All

Forward Voltage

V_F

2.7

I_F= 10 mA

(Nonresistor Lamps)

6800

9.6

13.0

5.0

Forward Current

(Resistor Lamps)

I_F

V_F= 5.0 V

6820

All

3.5

Reverse Breakdown

Voltage

V_R

5.0

50.0

I_R= 100 µA

P505

6505

125

Included Angle Between

Half Intensity Points^[2]

2θ /2

Deg.

All

Diffused

Peak Wavelength

λ_PEAK

λ_d

565

569

Dominant Wavelength^[3]

Spectral Line Half Width

Speed of Response

Capacitance

∆λ_1/2

τ_s

All

500

V_F= 0; f = 1 MHz

Thermal Resistance

Rθ_{J -PIN}

170

°C/W J unction-to-Cathode

Lead

Luminous Efficacy^[4]

η_v

595

lm/W

Not es:

1. The luminous intensity for arrays is tested to assure a 2.1 to 1.0 matching between elements. The average luminous

intensity for an array determines its light output category bin. Arrays are binned for luminous intensity to allow I_vmatching

between arrays.

2. θ¹/2 is the off-axis angle where the luminous intensity is half the on-axis value.

3. Dominant wavelength, λ_d, is derived from the CIE Chromaticity Diagram and represents the single wavelength that defines

the color of the device.

4. Radiant intensity, I_e, in watts/steradian, may be calculated from the equation I_e=I_v/η_v, where I_vis the luminous intensity in

candelas and η_vis the luminous efficacy in lumens/watt.

E m er a ld Gr een ^[1]

Device

H LMP -

P a r a m et er

Sym b ol Min . Typ . Ma x. Un it s

Test Con d it ion s

I_F= 10 mA

P605-F00xx Luminous Intensity

Q600-F00xx

I_v

1.0

1.5

2.2

mcd

Forward Voltage

V_F

V_R

3.0

I_F= 10 mA

All

Reverse Breakdown

Voltage

5.0

I_R= 100 µA

P605

Q600

Included Angle Between

Half Intensity Points^[2]

125

2θ /2

Deg.

558

560

Peak Wavelength

λ_PEAK

λ_d

Dominant Wavelength^[3]

Measured at Peak

V_F= 0; f = 1 MHz

Spectral Line Half Width ∆λ_1/2

P605/

Q600

Speed of Response

Capacitance

τ_s

3100

Thermal Resistance

Rθ_{J -PIN}

170

°C/W J unction-to-Cathode

Lead

Luminous Efficacy^[4]

η_v

656

lm/W

Not e:

1. Please refer to Application Note 1061 for information comparing standard green and emerald green light ouptut degradation.

F igu r e 1. R ela t ive In t en sit y vs. Wa velen gt h .

High Efficiency Red, Orange,

Yellow, High Performance

Green, and Emerald Green

Standard Red and DH AS

AlGaAs Red

100

HIGH EFFICIENCY

RED/ORANGE

YELLOW

HIGH

PERFORMANCE

GREEN,

EMERALD

GREEN

0.5

1.5

2.5

3.5

FORWARD VOLTAGE – V

F igu r e 2. F or w a r d Cu r r en t vs. F or w a r d Volt a ge. (Non -R esist or La m p )

HER, Orange, Yellow, and

High Performance Green,

and Emerald Green

Standard Red, DH As AlGaAs Red

Low Current

F igu r e 3. R ela t ive Lu m in ou s In t en sit y vs. F or w a r d Cu r r en t . (Non -R esist or La m p )

HER, Orange, Yellow, and

High Performance Green,

and Emerald Green

Standard Red

DH As AlGaAs Red

F igu r e 4. R ela t ive E fficien cy (Lu m in ou s In t en sit y p er Un it Cu r r en t ) vs. P ea k Cu r r en t (Non -R esist or La m p s).

F igu r e 5. Ma xim u m F or w a r d d c Cu r r en t vs. Am b ien t Tem p er a t u r e. Der a t in g Ba sed on T_JMAX =

110 °C (Non -R esist or La m p s).

HER, Orange, Yellow, and High

Standard Red

Performance Green

DH As AlGaAs Red

F igu r e 6. Ma xim u m Toler a b le P ea k Cu r r en t vs. P u lse Du r a t ion . (I_DCMAX a s p er MAX R a t in gs) (Non -R esist or

La m p s).

F igu r e 7. R esist or La m p F or w a r d Cu r r en t vs. F or w a r d

Volt a ge.

F igu r e 8. R esist or La m p Lu m in ou s In t en sit y vs.

F or w a r d Volt a ge.

F igu r e 9. R ela t ive In t en sit y vs. An gu la r Disp la cem en t .

www.semiconductor.agilent.com

Data subject to change.

December 29, 2000

Obsoletes 5968-7825E

5980-2149E

SubminiatureRightAngleLED

Indicators

TechnicalData

Option10

Features

•IdealforPCBoardStatus

Indication

•SideStackableon2.54mm

(0.100 in.) Centers

•AvailableinFourColors

•HousingMeetsUL94V-O

FlammabilityRating

•AdditionalCatalogLamps

AvailableasOptions

platedleadsareinlineon2.54

mm (0.100 in.) centers, a

Description

TheAgilentTechnolgiesseriesof

SubminiatureRightAngle

Indicatorsareindustrystandard

statusindicatorsthatincorporate

tinteddiffusedLEDlampsin

blackplastichousings.The2.54

mm (0.100 in.) wide packages

maybesidestackedformaximum

board space savings. The solder

standardspacingthatmakesthe

PCboardlayoutstraight-forward.

Theseproductsaredesignedtobe

usedasbackpaneldiagnostic

indicatorsandlogicstatus

indicatorsonPCboards.

PackageDimensions

OrderingInformation

AbsoluteMaximum

RatingsandOther

Electrical/Optical

Characteristics

Theabsolutemaximumratings

andtypicaldevicecharacteristics

areidenticaltothoseofthe

Subminiaturelamps.For

informationaboutthese

ToorderSubminiatureRight

Angleindicators,orderthebase

partnumberandaddtheoption

code10.Example:HLMP-6300-

F0010. Forpriceanddeliveryon

ResistorSubminiatureRight

AngleIndicatorsandother

subminiatureLEDsnotindicated

above,pleasecontactyour

nearestAgilentComponents

representative.

characteristics,seethedata

sheetsoftheequivalent

Subminiaturelamp.

Note:Option10isnotapplicable

forallAlInGaPandInGaN

devices.

HLMX-XXXX-X X X X X

Packaging

Option

Color Bin

Selection

Max. Iv Bin

Min. Iv Bin

4 x 4 Prod.

Part

Number

www.semiconductor.agilent.com

Data subject to change.

January 25, 2001

Obsoletes 5968-0056E (11/99)

5988-2176EN

HLMP-P202-F00 [AVAGO]

相关型号：

HLMP-P202-F0000

HLMP-P202-F0000

HLMP-P202-F0010

HLMP-P202-F0010

HLMP-P202-F0010

HLMP-P202-F0011

HLMP-P202-F0011

HLMP-P202-F0012

HLMP-P202-F0012

HLMP-P202-F001S

HLMP-P202-F001S

HLMP-P202-F0021