HIT HAT2033RJ, HAT2033R Datasheet

HAT2033R/HAT2033RJ

Silicon N Channel Power MOS FET

High Speed Power Switching

Features

• For Automotive Application ( at Type Code “J “)

• Low on-resistance

• Capable of 4 V gate drive

• High density mounting

Outline

ADE-208-664B (Z)

3rd. Edition

February 1999

SOP–8

4

G

56 7 8
D

D

DD

SSS
1

23

5

6

7

8

2

1

1, 2, 3 Source
4 Gate
5, 6, 7, 8 Drain

4

3

HAT2033R/HAT2033RJ

Absolute Maximum Ratings (Ta = 25°C)

Item Symbol Ratings Unit

Drain to source voltage V
Gate to source voltage V
Drain current I
Drain peak current I
Body-drain diode reverse drain current I
Avalanche current HAT2033R I

DSS

GSS

D

D(pulse)

DR

Note4

AP

Note1

HAT2033RJ 7 A

Avalanche energy HAT2033R E

Note4

AR

HAT2033RJ 4.2 mJ

Channel dissipation Pch

Note2

Channel temperature Tch 150 °C
Storage temperature Tstg – 55 to + 150 °C

Note: 1. PW ≤ 10µs, duty cycle ≤ 1 %

2. When using the glass epoxy board (FR4 40 x 40 x 1.6 mm), PW≤ 10s

3. Value at Tch=25°C, Rg≥50Ω

60 V
± 20 V
7A
56 A
7A
——

——

2.5 W

2

HAT2033R/HAT2033RJ

Electrical Characteristics (Ta = 25°C)

Item Symbol Min Typ Max Unit Test Conditions

Drain to source breakdown voltage V
Gate to source breakdown voltage V
Gate to source leak current I
Zero gate voltage HAT2033R I
drain current HAT2033RJ I
Zero gate voltage HAT2033R I
drain current HAT2033RJ I
Gate to source cutoff voltage V
Static drain to source on state R
resistance R

(BR)DSS

(BR)GSS

GSS

DSS

DSS

DSS

DSS

GS(off)

DS(on)

DS(on)

Forward transfer admittance |yfs| 6.5 10 — S ID = 4 A, VDS = 10 V
Input capacitance Ciss — 740 — pF VDS = 10 V
Output capacitance Coss — 370 — pF VGS = 0
Reverse transfer capacitance Crss — 130 — pF f = 1MHz
Turn-on delay time t
Rise time t
Turn-off delay time t
Fall time t
Body–drain diode forward voltage V
Body–drain diode reverse

t

d(on)

r

d(off)

f

DF

rr

recovery time
Note: 4. Pulse test

60——V ID = 10 mA, VGS = 0
± 20 — — V IG = ± 100 µA, VDS = 0
——± 10 µAVGS = ± 16 V, VDS = 0
——1 µAVDS = 60 V, VGS = 0
— — 0.1 µA
———µAVDS =4 8V , VGS = 0
——10µA Ta = 125°C

1.2 — 2.2 V VDS = 10 V, I D = 1 mA
— 0.03 0.038 Ω ID = 4 A, VGS = 10 V
— 0.04 0.053 Ω ID = 4 A, VGS = 4 V

—13—nsVGS =10 V, ID = 4 A
—55—nsVDD ≅ 30 V
— 140 — ns
—95—ns
— 0.82 1.07 V IF = 7 A, VGS = 0

Note4

— 45 — ns IF = 7 A , VGS = 0

diF/ dt = 50 A/µs

Note4

Note4

Note4

3