电子工程世界电子工程世界
Datasheet
型号
  • 型号
  • 关键词
X
首页
技术
模拟电子
单片机
半导体
电源管理
嵌入式
传感器
应用
汽车电子
工业控制
家用电子
手机便携
安防电子
医疗电子
网络通信
测试测量
物联网
大学堂
首页
直播
专题
TI 培训
论坛
TI 技术论坛
ST MEMS 传感器技术
单片机
电机驱动控制
模拟电子
电源技术
PCB 设计
RF/无线
电子竞赛
DIY/开源硬件专区
颁奖专区
活动中心
直播
发现活动
颁奖区
电子头条
参考设计
下载中心
分类资源
文集
排行榜
电路图
Datasheet
首页 > 器件类别 >

PJD09N03

25V N-Channel Enhancement Mode MOSFET

厂商名称:强茂(PANJIT)

厂商官网:http://www.panjit.com.tw/

下载文档
文档预览
PJD09N03
25V N-Channel Enhancement Mode MOSFET
TO-252
FEATURES
• R
DS(ON)
, V
GS
@10V,I
DS
@30A=9mΩ
• R
DS(ON)
, V
GS
@4.5V,I
DS
@30A=12mΩ
• Advanced trench process technology
• High Density Cell Design For Uitra Low On-Resistance
• Specially Designed for DC/DC Converters and Motor Drivers
• Fully Characterized Avalanche Voltage and Current
• Pb free product : 99% Sn above can meet RoHS environment
substance directive request
MECHANICALDATA
• Case: TO-252 Molded Plastic
• Terminals : Solderable per MIL-STD-202,Method 208
• Marking : 09N03
Drain
Gate
Source
Maximum RATINGS and Thermal Characteristics (T
A
=25
O
C unless otherwise noted )
PA RA M E TE R
D r a i n- S o ur c e Vo l t a g e
G a t e - S o ur c e Vo l t a g e
C o nt i nuo us D r a i n C ur r e nt
P ul s e d D r a i n C ur r e nt
1)
S ym b o l
V
D S
V
GS
I
D
I
D M
T
A
= 2 5
O
C
T
A
= 7 5
O
C
P
D
T
J
, T
S T G
E
AS
R
θ
J C
R
θ
J A
Li mi t
25
+20
50
240
45
26
-5 5 to + 1 5 0
130
2 .8
50
U ni t s
V
V
A
A
W
O
M a xi m um P o w e r D i s s i p a t i o n
O p e r a t i n g J u n c t i o n a n d S t o r a g e Te m p e r a t u r e R a n g e
Avalanche Energy with Single Pulse
ID=23A, VDD=25V, L=0.5mH
Junction-to-Case Thermal Resistance
Junction-to Ambient Thermal Resistance(PCB mounted)
2
C
mJ
O
C /W
C /W
O
Note: 1. Maximum DC current limited by the package
2. Surface mounted on FR4 board, t < 10 sec
PAN JIT RESERVES THE RIGHT TO IMPROVE PRODUCT DESIGN,FUNCTIONS AND RELIABILITY WITHOUT NOTICE
STAD-MAY.29.2006
PAGE . 1
PJD09N03
ELECTRICALCHARACTERISTICS
P a ra me te r
S ta ti c
D r a i n- S o ur c e B r e a k d o w n Vo l t a g e
G a t e Thr e s ho l d Vo l t a g e
D r a i n- S o ur c e O n- S t a t e R e s i s t a nc e
D r a i n- S o ur c e O n- S t a t e R e s i s t a nc e
Ze r o G a t e Vo l t a g e D r a i n C ur r e nt
Gate Body Leakage
Forward Transconductance
Dynamic
V
D S
= 1 5 V , I
D
= 1 5 A , V
G S
= 5 V
To t a l G a t e C h a r g e
Q
g
-
G a t e - S o ur c e C ha r g e
G a t e - D r a i n C ha r g e
Tu r n - O n D e l a y Ti m e
Tu r n - O n R i s e Ti m e
Tu r n - O f f D e l a y Ti m e
Tu r n - O f f F a l l Ti m e
In p u t C a p a c i t a n c e
O ut p ut C a p a c i t a nc e
R e v e r s e Tr a n s f e r C a p a c i t a n c e
S o ur c e - D r a i n D i o d e
M a x. D i o d e F o r w a r d C ur r e nt
D i o d e F o rwa rd Vo lta g e
I
s
V
SD
-
I
S
= 3 0 A , V
G S
= 0 V
-
-
-
0 .9 4
30
1 .2
A
V
Q
g s
Q
g d
T
d ( o n )
t
rr
t
d (o ff)
t
f
C
iss
C
oss
C
rs s
V
D S
=1 5 V, V
G S
=0 V
f=1 .0 MH
Z
V
D D
=15V , R
L
=15
I
D
=1A , V
G E N
=10V
R
G
=3.6
V
D S
= 1 5 V , I
D
= 1 5 A
V
G S
=10V
-
-
-
-
-
-
-
-
-
2 7 .5
3 .5
7 .2
10.0
11.0
35
11 . 2
1250
240
185
-
nC
-
-
13.0
14.0
ns
45
1 5 .5
-
-
-
pF
-
1 6 .0
-
BV
D SS
V
G S (th)
R
D S (o n)
R
D S (o n)
I
D S S
I
G S S
g
fS
V
G S
= 0 V , I
D
= 2 5 0 u A
V
D S
= V
G S
, I
D
= 2 5 0 u A
V
G S
=4.5V, I
D
=30A
V
G S
=10V, I
D
=30A
V
D S
=25V, V
G S
=0V
V
G S
=+2 0 V, V
D S
=0 V
V
D S
= 1 0 V , I
D
= 1 5 A
25
1
-
-
-
-
25
-
-
9 .5
6.5
-
-
-
-
3
1 2 .0
m
9.0
1
+100
-
uA
nA
S
V
V
S ym b o l
Te s t C o n d i t i o n
M i n.
Ty p .
M a x.
U ni t s
Switching
Test Circuit
V
IN
V
DD
R
L
V
OUT
Gate Charge
Test Circuit
V
GS
V
DD
R
L
R
G
1mA
R
G
STAD-MAY.29.2006
PAGE . 2
PJD09N03
Typical Characteristics Curves (T
A
=25
O
C,unless otherwise noted)
I
D
- Drain-to-Source Current (A)
80
80
I
D
- Drain Source Current (A)
V
GS
=10V, 6.0V, 5.0V, 4.5V, 4.0V
60
V
DS
=10V
3.5V
60
40
40
T
J
=125 C
O
3.0V
20
20
2.5V
0
T
J
=25 C
O
T
J
=-55 C
O
0
0
1
2
3
4
5
1.5
2
2.5
3
3.5
4
4.5
V
DS
- Drain-to-Source Voltage (V)
V
GS
- Gate-to-Source Voltage (V)
Fig. 1-TYPICAL FORWARD CHARACTERISTIC
FIG.1- Output Characteristic
FIG.2- Transfer Characteristic
20
50
R
DS(ON)
- On-Resistance (m
W
)
R
DS(ON)
- On-Resistance (m
W
)
I
D
=30A
15
40
10
V
GS
=4.5V
30
20
125
o
C
T
J
=125 C
O
5
V
GS
=10V
10
T
J
=25
C
T
J
=25
o
C
O
0
0
0
20
40
60
80
2
4
6
8
10
I
D
- Drain Current (A)
V
GS
- Gate-to-Source Voltage (V)
FIG.3- On Resistance vs Drain Current
FIG.4- On Resistance vs Gate to Source Voltage
R
DS(ON)
- On-Resistance(Normalized)
1.6
1.4
1.2
V
GS
=10V
I
D
=30A
1
0.8
0.6
-50
-25
0
25
50
75
100
125
150
T
J
- Junction Temperature (
o
C)
FIG.5- On Resistance vs Junction Temperature
STAD-MAY.29.2006
PAGE . 3
PJD09N03
10
Vgs
Qg
V
GS
- Gate-to-Source Voltage (V)
8
6
4
2
0
V
DS
=15V
I
D
=15A
Vgs(th)
Qg(th)
Qgs
Qsw
0
5
10
15
20
25
30
Qgd
Qg
Q
g
- Gate Charge (nC)
Fig.6 - Gate Charge Waveform
V
th
- G-S Threshold Voltage (NORMALIZED)
Fig.7 - Gate Charge
BV
DSS
- Breakdown Voltage (V)
1.3
1.2
1.1
1
0.9
0.8
0.7
0.6
-50
I
D
=250uA
29
I
D
=250uA
28
27
26
-25
0
25
50
75
100
125
150
25
-50
-25
0
25
50
75
100
125
150
T
J
- Junction Temperature (
o
C)
T
J
- Junction Temperature (
o
C)
Fig.8 - Threshold Voltage vs Temperature
Fig.9 - Breakdown Voltage vs Junction Temperature
100
V
GS
=0V
I
S
- Source Current (A)
10
T
J
=125
O
C
1
T
J
=25
O
C
T
J
=-55
O
C
0.1
0.2
0.4
0.6
0.8
1
1.2
1.4
V
SD
- Source-to-Drain Voltage (V)
Fig.10 - Source-Drain Diode Forward Voltage
LEGALSTATEMENT
Copyright PanJit International, Inc 2006
The information presented in this document is believed to be accurate and reliable. The specifications and information herein
are subject to change without notice. Pan Jit makes no warranty, representation or guarantee regarding the suitability of its
products for any particular purpose. Pan Jit products are not authorized for use in life support devices or systems. Pan Jit
does not convey any license under its patent rights or rights of others.
STAD-MAY.29.2006
PAGE . 4
查看更多>
EG2133的高端输出异常
示波器观察EG2133高端输出一直为高电平,低端输出正常,请问一下大家时什么原因?EG2133的高端输出异常猜测EG2133芯片挂了,过两天换一个直接上电后,由于内部上拉电阻以及HO端下拉电阻的存在,所以通常情况下HO端应该为低电平,现在一直保持高电平不变,猜测EG2133芯片问题你好我也遇到和你一样的问题了,我更换芯片后发现高端输出在高电平的基准上有一个不太标准的PWM波,且并未抬高目标电压,上了几次电后高端输出又称常高了。请问当时你的问题时怎么解决的?...
史上最萌反派 电机驱动控制(Motor Control)
ADM2483BRWZ 输入输出问题
我最近在测试ADM2483BRWZ电路信号时,发现,如下波形。其中蓝色是RE/DE(一起控制)信号,绿色是TXD波形,黄色是RXD波形。问题:为什么RE/DE(一起控制)信号为高定平时,RXD的信号有抖动,这种波形对吗?ADM2483BRWZ输入输出问题我看手册RE为高电平时EXD不应该有信号,这种干扰可能是RXD在高阻状态下收到TXD干扰引起的,你弄一个上拉看一下能不能把信号控制在高电平。正常现象,处于接收态但总线却浮空时就会感应电磁干扰。 那为了保证不受干扰...
bioger ADI参考电路
128X64LCD驱动
各位,附件内为源代码,请问为什么不能显示字符,谢帮帮忙,谢谢128X64LCD驱动...
eeworld.com 单片机
找资料的时候找到的:STM32F7-Discovery iconview理解与修改
在找资料时找到一个关于iconview自绘的资——网址如下,看得不是很懂。http://www.dt-tech.net/Dteam/f7/iconviewEx/找资料的时候找到的:STM32F7-Discoveryiconview理解与修改...
hgg2008 stm32/stm8
GD32F350体验之九(freemodbus的使用)
在前面已经说明了freemodbus在GD32的另类移植办法。接下来就是说明如何利用freemodbus这个抽象化的协议栈上,更快速地开发自己的通信应用部分。Freemodbus在获取到一帧数据之后,如果功能码对应的上,则通过查表跳转到相对应的执行函数当中,比如写多个保持寄存器的功能码为0x16,则跳转到eMBFuncWriteMultipleHoldingRegister函数,file:///C:/Users/RCSN/AppData/Local/Temp/msohtmlclip1...
RCSN GD32 MCU
数字工程师为何不相信EMC(转载)
我最近参加了IEEE电磁兼容性(EMC)学会的一个本地(西雅图)会议,这并不是我所居住的地方,但我极力向你推荐,在这里你可以了解更多的EMC的基本知识,还可以获取大量的免费建议。听完BillRitenour关于汽油泵的静电屏蔽的演讲之后,我们开始关注另一个问题,即:为具有纯数字背景的人员讲授EMC概念的优势何在?讨论得出结果后又经过反复思考,现在我终于能够指出众多数字工程师难以处理EMC问题的基本原因。与模拟世界的一些观点相反,这并不是因为他们没有说话能力,也不是因为...
settleinsh 单片机