FDD8870 [ONSEMI]

N 沟道，PowerTrench® MOSFET，30V，160A，3.9mΩ;


型号：	FDD8870
厂家：	ONSEMI
描述：	N 沟道，PowerTrench® MOSFET，30V，160A，3.9mΩ 开关晶体管
文件：	总13页 (文件大小：512K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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March 2015

FDD8870 / FDU8870

N-Channel PowerTrench MOSFET

30V, 160A, 3.9mΩ

General Description

Features

This N-Channel MOSFET has been designed specifically to

improve the overall efficiency of DC/DC converters using

either synchronous or conven tional swit ching PW M

controllers. It has been optimized for low gate charge, low

•

= 3.9mΩ, V = 10V, I = 35A

GS D

DS(ON)

= 4.4mΩ, V = 4.5V, I = 35A

DS(ON)

High performance trench technology for extremely low

and fast switching speed.

DS(ON)

•

Low gate charge

Applications

High power and current handling capability

•

DC/DC converters

I-PAK

(TO-251AA)

D-PAK

TO-252

(TO-252)

G D S

MOSFET Maximum Ratings ^T= 25°C unless otherwise noted

Symbol

Parameter

Ratings

Units

Drain to Source Voltage

Gate to Source Voltage

DSS

±20

Drain Current

160

150

Continuous (T = 25 C, V = 10V) (Note 1)

Continuous (T = 25 C, V = 4.5V) (Note 1)

C GS

Continuous (T

= 25 C, V = 10V, with R = 52 C/W)

θJA

amb

Pulsed

Figure 4

690

Single Pulse Avalanche Energy (Note 2)

Power dissipation

160

Derate above 25 C

1.07

W/ C

T , T

Operating and Storage Temperature

-55 to 175

STG

Thermal Characteristics

Thermal Resistance Junction to Case TO-252, TO-251

Thermal Resistance Junction to Ambient TO-252, TO-251

0.94

100

C/W

θJC

θJA

C/W

Thermal Resistance Junction to Ambient TO-252, 1in copper pad area

C/W

FDD8870 / FDU8870 Rev. 1.2

Package Marking and Ordering Information

Device Marking

Device

FDD8870

FDU8870

Package

TO-252AA

TO-251AA

Reel Size

13”

Tape Width

16mm

Quantity

2500 units

75 units

FDD8870

FDU8870

Tube

N/A

Electrical Characteristics ^T= 25°C unless otherwise noted

Symbol

Parameter

Test Conditions

Min

Typ

Max

Units

Off Characteristics

Drain to Source Breakdown Voltage

Zero Gate Voltage Drain Current

Gate to Source Leakage Current

= 250µA, V = 0V

VDSS

= 24V

= 0V

µA

DSS

= 150 C

250

±100

= ±20V

GSS

On Characteristics

Gate to Source Threshold Voltage

= V , I = 250µA

1.2

2.5

GS(TH)

= 35A, V = 10V

0.0032 0.0039

0.0036 0.0044

= 35A, V = 4.5V

Drain to Source On Resistance

Ω

DS(ON)

= 35A, V = 10V,

0.0051 0.0063

T = 175 C

Dynamic Characteristics

Input Capacitance

5160

990

590

2.1

Ω

ISS

OSS

RSS

= 15V, V = 0V,

Output Capacitance

f = 1MHz

Reverse Transfer Capacitance

Gate Resistance

= 0.5V, f = 1MHz

= 0V to 10V

Total Gate Charge at 10V

Total Gate Charge at 5V

Threshold Gate Charge

Gate to Source Gate Charge

Gate Charge Threshold to Plateau

Gate to Drain “Miller” Charge

118

6.5

g(TOT)

g(5)

g(TH)

= 0V to 5V

= 15V

= 35A

= 0V to 1V

I = 1.0mA

gs2

Switching Characteristics (V = 10V)

Turn-On T ime

Turn-On Delay Time

Rise Time

139

d(ON)

= 15V, I = 35A

= 10V, R = 3.3Ω

Turn-Off Delay Time

Fall Time

d(OFF)

Turn-Off Time

189

OFF

Drain-Source Diode Characteristics

= 35A

= 15A

1.25

1.0

Source to Drain Diode Voltage

Reverse Recovery Time

= 35A, dI /dt = 100A/µs

Reverse Recovered Charge

= 35A, dI /dt = 100A/µs

Notes:

1: Package current limitation is 35A.

2: Starting T = 25°C, L = 1.77mH, I = 28A, V = 27V, V = 10V.

FDD8870 / FDU8870 Rev. 1.2

Typical Characteristics ^T= 25°C unless otherwise noted

1.2

175

1.0

0.8

0.6

0.4

0.2

150

125

100

CURRENT LIMITED

BY PACKAGE

100

150

175

125

175

100

125

150

, CASE TEMPERATURE ( C)

Figure 1. Normalized Power Dissipation vs Case

Temperature

Figure 2. Maximum Continuous Drain Current vs

Case Temperature

DUTY CYCLE - DESCENDING ORDER

0.5

0.2

0.1

0.05

0.02

0.01

0.1

NOTES:

DUTY FACTOR: D = t /t

SINGLE PULSE

0.01

PEAK T = P

x Z

x R

+ T

θJC C

θJC

-5

-4

-3

-2

-1

t, RECTANGULAR PULSE DURATION (s)

Figure 3. Normalized Maximum Transient Thermal Impedance

2000

= 25 C

TRANSCONDUCTANCE

MAY LIMIT CURRENT

IN THIS REGION

FOR TEMPERATURES

1000

ABOVE 25 C DERATE PEAK

CURRENT AS FOLLOWS:

= 4.5V

175 - T

150

I = I

100

-5

-4

-3

-2

-1

t, PULSE WIDTH (s)

Figure 4. Peak Current Capability

FDD8870 / FDU8870 Rev. 1.2

Typical Characteristics ^T= 25°C unless otherwise noted

1000

100

10µs

STARTING T = 25 C

100µs

STARTING T = 150 C

OPERATION IN THIS

AREA MAY BE

1ms

LIMITED BY r

DS(ON)

10ms

If R = 0

SINGLE PULSE

= (L)(I )/(1.3*RATED BV

- V

)

DSS

= MAX RATED

= 25 C

If R ≠ 0

= (L/R)ln[(I *R)/(1.3*RATED BV

- V ) +1]

DSS DD

0.1

, DRAIN TO SOURCE VOLTAGE (V)

0.1

100

t , TIME IN AVALANCHE (ms)

NOTE: Refer to Fairchild Application Notes AN7514 and AN7515

Figure 6. Unclamped Inductive Switching

Capability

Figure 5. Forward Bias Safe Operating Area

100

PULSE DURATION = 80µs

= 5V

DUTY CYCLE = 0.5% MAX

= 15V

= 4V

= 10V

= 175 C

= 3V

= 25 C

= 2.5V

= 25 C

PULSE DURATION = 80µs

DUTY CYCLE = 0.5% MAX

= -55 C

0.2

0.4

0.6

1.5

2.0

2.5

3.0

, GATE TO SOURCE VOLTAGE (V)

, DRAIN TO SOURCE VOLTAGE (V)

Figure 7. Transfer Characteristics

Figure 8. Saturation Characteristics

1.6

PULSE DURATION = 80µs

DUTY CYCLE = 0.5% MAX

PULSE DURATION = 80µs

DUTY CYCLE = 0.5% MAX

= 35A

1.4

1.2

1.0

0.8

0.6

= 1A

= 10V, I = 35A

-80

-40

120

160

200

, GATE TO SOURCE VOLTAGE (V)

T , JUNCTION TEMPERATURE ( C)

Figure 9. Drain to Source On Resistance vs Gate

Voltage and Drain Current

Figure 10. Normalized Drain to Source On

Resistance vs Junction Temperature

FDD8870 / FDU8870 Rev. 1.2

Typical Characteristics ^T= 25°C unless otherwise noted

1.2

1.0

0.8

0.6

0.4

1.2

1.1

1.0

0.9

= 250µA

= V , I = 250µA

DS D

-80

-40

120

160

200

-80

-40

120

160

200

T , JUNCTION TEMPERATURE ( C)

Figure 11. Normalized Gate Threshold Voltage vs

Junction Temperature

Figure 12. Normalized Drain to Source

Breakdown Voltage vs Junction Temperature

10000

= 15V

= C + C

GS GD

ISS

+ C

OSS

DS GD

= C

RSS

1000

400

WAVEFORMS IN

DESCENDING ORDER:

= 35A

= 5A

= 0V, f = 1MHz

100

0.1

, DRAIN TO SOURCE VOLTAGE (V)

Q , GATE CHARGE (nC)

Figure 13. Capacitance vs Drain to Source

Voltage

Figure 14. Gate Charge Waveforms for Constant

Gate Current

FDD8870 / FDU8870 Rev. 1.2

Test Circuits and Waveforms

DSS

VARY t TO OBTAIN

REQUIRED PEAK I

DUT

0.01Ω

Figure 15. Unclamped Energy Test Circuit

Figure 16. Unclamped Energy Waveforms

g(TOT)

= 10V

g(5)

gs2

= 5V

DUT

= 1V

g(REF)

g(TH)

g(REF)

Figure 17. Gate Charge Test Circuit

Figure 18. Gate Charge Waveforms

OFF

d(OFF)

d(ON)

90%

10%

DUT

90%

50%

PULSE WIDTH

10%

Figure 19. Switching Time Test Circuit

Figure 20. Switching Time Waveforms

FDD8870 / FDU8870 Rev. 1.2

Thermal Resistance vs. Mounting Pad Area

The max imum rated junct ion temperature, T , and t he

thermal resistance of the heat dissipating path determines

125

100

= 33.32+ 23.84/(0.268+Area) EQ.2

= 33.32+ 154/(1.73+Area) EQ.3

θJA

the maximum allowable device power dissipation, P , in an

application.

Therefore t he application’s ambient

θJA

temperature, T ( C), and t hermal resistance R

( C/W)

θJA

must be rev iewed to ens ure that T

is never ex ceeded.

Equation 1 mathematically represents the relationship and

serves as the basis for establishing the rating of the part.

– T )

(EQ. 1)

= -----------------------------

R_θJA

In us ing surf ace m ount dev ices s uch as t he T O-252

package, the environment in which it is applied will have a

significant inf luence on t he part’s cur rent and m aximum

0.01

(0.0645)

0.1

(0.645)

(6.45)

(64.5)

power dissipation ratings. Precise determination of P

complex and influenced by many factors:

AREA, TOP COPPER AREA in (cm )

Figure 21. Thermal Resistance vs Mounting

Pad Area

1. Mounting pad area onto which the device is attached and

whether there is copper on one side or both sides of the

board.

2. T he number of copper layers and t he thickness of the

board.

3. The use of external heat sinks.

4. The use of thermal vias.

5. Air flow and board orientation.

6. For non steady state applications, the pulse width, the

duty cycle and the transient thermal response of the part,

the board and the environment they are in.

Fairchild provides t hermal i nformation t o as sist the

designer’s preliminary application evaluat ion. F igure 21

defines t he R

f or t he device as a f unction of t he top

θJA

copper (component s ide) area. T his is f or a horizont ally

positioned FR-4 board with 1oz copper after 1000 seconds

of steady state power with no air flow. This graph provides

the necessary information for calculation of the steady state

junction temperature or power

dissipat ion. P ulse

applications can be ev aluated us ing t he F airchild dev ice

Spice thermal model o r m anually ut ilizing the norm alized

maximum transient thermal impedance curve.

Thermal resistances corresponding to other copper areas

can be obt ained f rom Figure 21 or by calc ulation using

Equation 2 or 3. Equation 2 is used for copper area defined

in inches square and equation 3 is for area in c entimeters

square. The area, in square inches or square centimeters is

the top copper area including the gate and source pads.

23.84

(0.268 + Area)

= 33.32 + ------------------------------------

(EQ. 2)

θJA

Area in Inches Squared

154

= 33.32 + ---------------------------------

(EQ. 3)

(1.73 + Area)

Area in Centimeters Squared

FDD8870 / FDU8870 Rev. 1.2

PSPICE Electrical Model

.SUBCKT FDD8870 2 1 3 ; rev July 2003

Ca 12 8 4.2e-9

Cb 15 14 4.2e-9

Cin 6 8 4.7e-9

LDRAIN

DPLCAP

DRAIN

Dbody 7 5 DbodyMOD

Dbreak 5 11 DbreakMOD

Dplcap 10 5 DplcapMOD

RLDRAIN

RSLC1

DBREAK

RSLC2

ESLC

Ebreak 11 7 17 18 32.7

Eds 14 8 5 8 1

Egs 13 8 6 8 1

Esg 6 10 6 8 1

Evthres 6 21 19 8 1

Evtemp 20 6 18 22 1

GATE

DBODY

RDRAIN

EBREAK 18

ESG

EVTHRES

MWEAK

LGATE

EVTEMP

RGATE

MMED

It 8 17 1

MSTRO

RLGATE

Lgate 1 9 5e-9

Ldrain 2 5 1.0e-9

LSOURCE

CIN

SOURCE

Lsource 3 7 2e-9

RSOURCE

RLSOURCE

RLgate 1 9 50

RLdrain 2 5 10

RLsource 3 7 20

S1A

S2A

RBREAK

RVTEMP

S1B

S2B

Mmed 16 6 8 8 MmedMOD

Mstro 16 6 8 8 MstroMOD

Mweak 16 21 8 8 MweakMOD

VBAT

EGS

EDS

Rbreak 17 18 RbreakMOD 1

Rdrain 50 16 RdrainMOD 1.57e-3

Rgate 9 20 2.1

RVTHRES

RSLC1 5 51 RSLCMOD 1e-6

RSLC2 5 50 1e3

Rsource 8 7 RsourceMOD 1.2e-3

Rvthres 22 8 RvthresMOD 1

Rvtemp 18 19 RvtempMOD 1

S1a 6 12 13 8 S1AMOD

S1b 13 12 13 8 S1BMOD

S2a 6 15 14 13 S2AMOD

S2b 13 15 14 13 S2BMOD

Vbat 22 19 DC 1

ESLC 51 50 VALUE={(V(5,51)/ABS(V(5,51)))*(PWR(V(5,51)/(1e-6*500),10))}

.MODEL DbodyMOD D (IS=1.3E-11 IKF=10 N=1.01 RS=1.8e-3 TRS1=8e-4 TRS2=2e-7

+ CJO=2e-9 M=0.57 TT=1e-10 XTI=0.9)

.MODEL DbreakMOD D (RS=8e-2 TRS1=1e-3 TRS2=-8.9e-6)

.MODEL DplcapMOD D (CJO=1.6e-9 IS=1e-30 N=10 M=0.38)

.MODEL MmedMOD NMOS (VTO=1.76 KP=10 IS=1e-30 N=10 TOX=1 L=1u W=1u RG=2.1 T_ABS=25)

.MODEL MstroMOD NMOS (VTO=2.2 KP=650 IS=1e-30 N=10 TOX=1 L=1u W=1u T_ABS=25)

.MODEL MweakMOD NMOS (VTO=1.47 KP=0.05 IS=1e-30 N=10 TOX=1 L=1u W=1u RG=21 RS=0.1 T_ABS=25)

.MODEL RbreakMOD RES (TC1=8.3e-4 TC2=-4e-7)

.MODEL RdrainMOD RES (TC1=2e-4 TC2=8e-6)

.MODEL RSLCMOD RES (TC1=9e-4 TC2=1e-6)

.MODEL RsourceMOD RES (TC1=8e-3 TC2=1e-6)

.MODEL RvthresMOD RES (TC1=-2e-3 TC2=-9.5e-6)

.MODEL RvtempMOD RES (TC1=-2.6e-3 TC2=2e-7)

.MODEL S1AMOD VSWITCH (RON=1e-5 ROFF=0.1 VON=-4 VOFF=-3)

.MODEL S1BMOD VSWITCH (RON=1e-5 ROFF=0.1 VON=-3 VOFF=-4)

.MODEL S2AMOD VSWITCH (RON=1e-5 ROFF=0.1 VON=-2 VOFF=-0.5)

.MODEL S2BMOD VSWITCH (RON=1e-5 ROFF=0.1 VON=-0.5 VOFF=-2)

.ENDS

Note: For further discussion of the PSPICE model, consult A New PSPICE Sub-Circuit for the Power MOSFET Featuring Global

Temperature Options; IEEE Power Electronics Specialist Conference Records, 1991, written by William J. Hepp and C. Frank

Wheatley.

FDD8870 / FDU8870 Rev. 1.2

SABER Electrical Model

rev July 2003

template FDD8870 n2,n1,n3 =m_temp

electrical n2,n1,n3

number m_temp=25

{

var i iscl

dp..model dbodymod = (isl=1.3e-11,ikf=10,nl=1.01,rs=1.8e-3,trs1=8e-4,trs2=2e-7,cjo=2e-9,m=0.57,tt=1e-10,xti=0.9)

dp..model dbreakmod = (rs=8e-2,trs1=1e-3,trs2=-8.9e-6)

dp..model dplcapmod = (cjo=1.6e-9,isl=10e-30,nl=10,m=0.38)

m..model mmedmod = (type=_n,vto=1.76,kp=10,is=1e-30, tox=1)

m..model mstrongmod = (type=_n,vto=2.2,kp=650,is=1e-30, tox=1)

m..model mweakmod = (type=_n,vto=1.47,kp=0.05,is=1e-30, tox=1,rs=0.1)

LDRAIN

sw_vcsp..model s1amod = (ron=1e-5,roff=0.1,von=-4,voff=-3)

sw_vcsp..model s1bmod = (ron=1e-5,roff=0.1,von=-3,voff=-4)

sw_vcsp..model s2amod = (ron=1e-5,roff=0.1,von=-2,voff=-0.5)

sw_vcsp..model s2bmod = (ron=1e-5,roff=0.1,von=-0.5,voff=-2)

c.ca n12 n8 = 4.2e-9

DPLCAP

DRAIN

RLDRAIN

RSLC1

RSLC2

c.cb n15 n14 = 4.2e-9

c.cin n6 n8 = 4.7e-9

ISCL

DBREAK

dp.dbody n7 n5 = model=dbodymod

dp.dbreak n5 n11 = model=dbreakmod

dp.dplcap n10 n5 = model=dplcapmod

RDRAIN

ESG

DBODY

EVTHRES

MWEAK

LGATE

EVTEMP

spe.ebreak n11 n7 n17 n18 = 32.7

RGATE

GATE

EBREAK

spe.eds n14 n8 n5 n8 = 1

spe.egs n13 n8 n6 n8 = 1

spe.esg n6 n10 n6 n8 = 1

spe.evthres n6 n21 n19 n8 = 1

spe.evtemp n20 n6 n18 n22 = 1

MMED

MSTRO

RLGATE

LSOURCE

CIN

SOURCE

RSOURCE

RLSOURCE

i.it n8 n17 = 1

S1A

S2A

RBREAK

l.lgate n1 n9 = 5e-9

l.ldrain n2 n5 = 1.0e-9

l.lsource n3 n7 = 2e-9

RVTEMP

S1B

S2B

res.rlgate n1 n9 = 50

res.rldrain n2 n5 = 10

res.rlsource n3 n7 = 20

VBAT

EGS

EDS

m.mmed n16 n6 n8 n8 = model=mmedmod, l=1u, w=1u, temp=m_temp

m.mstrong n16 n6 n8 n8 = model=mstrongmod, l=1u, w=1u, temp=m_temp

m.mweak n16 n21 n8 n8 = model=mweakmod, l=1u, w=1u, temp=m_temp

RVTHRES

res.rbreak n17 n18 = 1, tc1=8.3e-4,tc2=-4e-7

res.rdrain n50 n16 = 1.57e-3, tc1=2e-4,tc2=8e-6

res.rgate n9 n20 = 2.1

res.rslc1 n5 n51 = 1e-6, tc1=9e-4,tc2=1e-6

res.rslc2 n5 n50 = 1e3

res.rsource n8 n7 = 1.2e-3, tc1=8e-3,tc2=1e-6

res.rvthres n22 n8 = 1, tc1=-2e-3,tc2=-9.5e-6

res.rvtemp n18 n19 = 1, tc1=-2.6e-3,tc2=2e-7

sw_vcsp.s1a n6 n12 n13 n8 = model=s1amod

sw_vcsp.s1b n13 n12 n13 n8 = model=s1bmod

sw_vcsp.s2a n6 n15 n14 n13 = model=s2amod

sw_vcsp.s2b n13 n15 n14 n13 = model=s2bmod

v.vbat n22 n19 = dc=1

equations {

i (n51->n50) +=iscl

iscl: v(n51,n50) = ((v(n5,n51)/(1e-9+abs(v(n5,n51))))*((abs(v(n5,n51)*1e6/500))** 10))

}

FDD8870 / FDU8870 Rev. 1.2

PSPICE Thermal Model

JUNCTION

REV 23 July 2003

FDD8870T

CTHERM1 TH 6 1e-3

CTHERM2 6 5 2e-3

CTHERM3 5 4 3e-3

CTHERM4 4 3 9e-3

CTHERM5 3 2 1e-2

CTHERM6 2 TL 2e-2

RTHERM1

RTHERM2

RTHERM3

RTHERM4

RTHERM5

RTHERM6

CTHERM1

RTHERM1 TH 6 3e-2

RTHERM2 6 5 8e-2

RTHERM3 5 4 1.1e-1

RTHERM4 4 3 1.6e-1

RTHERM5 3 2 1.72e-1

RTHERM6 2 TL 2e-1

CTHERM2

CTHERM3

CTHERM4

CTHERM5

CTHERM6

SABER Thermal Model

SABER thermal model FDD8870T

template thermal_model th tl

thermal_c th, tl

{

ctherm.ctherm1 th 6 =1e-3

ctherm.ctherm2 6 5 =2e-3

ctherm.ctherm3 5 4 =3e-3

ctherm.ctherm4 4 3 =9e-3

ctherm.ctherm5 3 2 =1e-2

ctherm.ctherm6 2 tl =2e-2

rtherm.rtherm1 th 6 =3e-2

rtherm.rtherm2 6 5 =8e-2

rtherm.rtherm3 5 4 =1.1e-1

rtherm.rtherm4 4 3 =1.6e-1

rtherm.rtherm5 3 2 =1.72e-1

rtherm.rtherm6 2 tl =2e-1

}

CASE

FDD8870 / FDU8870 Rev. 1.2

ON Semiconductor and

are trademarks of Semiconductor Components Industries, LLC dba ON Semiconductor or its subsidiaries in the United States and/or other countries.

ON Semiconductor owns the rights to a number of patents, trademarks, copyrights, trade secrets, and other intellectual property. A listing of ON Semiconductor’s product/patent

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