MC34845EPR2 (Freescale) PDF资料下载 Datasheet(18/24 页)

您好，
买卖IC网欢迎您。
请登录
免费注册

您现在的位置：买卖IC网 > PDF目录20647 > MC34845EPR2 (Freescale Semiconductor)IC DVR LED BACKLIGHT 6CH 24-QFN PDF资料下载

参数资料

型号：	MC34845EPR2
厂商：	Freescale Semiconductor
文件页数：	18/24页
文件大小：	0K
描述：	IC DVR LED BACKLIGHT 6CH 24-QFN
标准包装：	2,500
拓扑：	PWM，升压（升压）
输出数：	6
内部驱动器：	是
类型 - 主要：	背光
频率：	600kHz
电源电压：	5 V ~ 21 V
输出电压：	8 V ~ 60 V
安装类型：	表面贴装
封装/外壳：	24-UFQFN 裸露焊盘
供应商设备封装：	24-QFN 裸露焊盘（4x4）
包装：	带卷 (TR)
工作温度：	-40°C ~ 85°C

第1页第2页第3页第4页第5页第6页第7页第8页第9页第10页第11页第12页第13页第14页第15页第16页第17页当前第18页第19页第20页第21页第22页第23页第24页

TYPICAL APPLICATIONS

COMPONENTS CALCULATION

COMPONENTS CALCULATION

The following formulas are intended for the calculation of

all external components related with the boost converter and

network compensation.

= I OUT × -------------

In order to calculate the Duty Cycle, the internal losses of

the MOSFET and Diode should be taken into consideration:

I RMS – C

OUT

D

1 – D

V OUT + V D – V IN

D = -----------------------------------------------

V OUT + V D – V SW

I IN – AVG = -------------

( V IN – V SW – ( I IN – AVG × R INDUCTOR ) ) × D

I IN – AVG × r × F SW

V OUT × ( 1 – D )

I OUT × 2 π × L

2 × L × F SW × V OUT

f CROSS = ---------------

The average input current depends directly on the output

current when the internal switch is off.

I OUT

1 – D

Inductor

For calculating the Inductor, consider the losses of the

internal switch and winding resistance of the inductor:

L = ------------------------------------------------------------------------------------------------------------------

It is important to look for an inductor rated at least for the

maximum input current:

V IN × ( V OUT – V IN )

I IN – MAX = I IN – AVG + ---------------------------------------------------------

Input Capacitor

The input capacitor should handle at least the following

RMS current.

Note that before calculating the network compensation, all

boost converter components need to be known.

For this type of compensation it is recommended to push

out the Right Half Plane Zero to higher frequencies where it

will not significantly affect the overall loop.

2

f RHPZ = ---------------------------------------------

The crossover frequency must be set much lower than the

location of the Right half plane zero:

f RHPZ

5

Since our system has a fixed slope compensation, R COMP

? V IN × ( V OUT – V IN ) ?

? 2 × L × F SW × V OUT ?

I RMS – C

IN

= ? --------------------------------------------------------- ? × 0.3

should be fixed for all configurations, i.e. R COMP = 2 Kohm

C COMP1 and C COMP2 should be calculated as follows:

C COMP1 = -------------------------------------------------------------

π × f CROSS × COMP

( 1 – D ) × V OUT × 0.35

V OUT × Δ V OUT × F SW × L

ESR C

V OUT × ( 1 – D )

6.28 × F SW

Output Capacitor

For the output capacitor selection the transconductance

should be taken in consideration.

R COMP × 5 × G M × I OUT × L

C OUT = -------------------------------------------------------------------------------

The output voltage ripple ( Δ V OUT ) depends on the ESR of

the Output capacitor. For a low output voltage ripple, it is

recommended to use ceramic capacitors that have a very low

ESR. Since ceramic capacitor are costly, electrolytic or

tantalum capacitors can be mixed with ceramic capacitors for

a less expensive solution.

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

OUT

The output capacitor should at least handle the following

RMS current.

Network Compensation

Since this Boost converter is current controlled, a Type II

compensation is needed.

2

R

2 GM

C COMP2 = -----------------------------

The recommended values of these capacitors for an

acceptable performance of the system in different operating

conditions are Ccomp1=33nF and Ccomp2=220pF.

In order to improve the transient response of the boost a

resistor network can be implemented from the PWM pin to

ground with a connection to the compensation network. This

configuration should inject a 1V signal to the COMP pin and

the equivalent Thevenin resistance of the divider should be

close to R COMP , (i.e. for 2k COMP resistor, R COMP = 3.3k and

R SHUNT = 10k. See Figure 10 , Figure 11 and Figure 12 for

implementation guidelines.

If a faster transient response is needed, a higher voltage

(e.g. 1.3V) should be injected to the COMP pin; so the

resistor divider should be modified accordingly but keeping

the equivalent Thevenin resistance of the divider close to

R COMP .

34845

Analog Integrated Circuit Device Data

18

Freescale Semiconductor

相关PDF资料	PDF描述
VE-J6W-CX-F4	CONVERTER MOD DC/DC 5.5V 75W
T95Z107K004CSSL	CAP TANT 100UF 4V 10% 2910
EEC13DRAN	CONN EDGECARD 26POS R/A .100 SLD
VE-BNX-EU-F3	CONVERTER MOD DC/DC 5.2V 200W
HCC60DRTN-S93	CONN EDGECARD 120PS DIP .100 SLD

相关代理商/技术参数	参数描述
MC34846EP	功能描述:LED照明驱动器 6-Ch LED Backlt Drvr RoHS:否制造商:STMicroelectronics 输入电压:11.5 V to 23 V 工作频率: 最大电源电流:1.7 mA 输出电流: 最大工作温度: 安装风格:SMD/SMT 封装 / 箱体:SO-16N
MC34846EPR2	功能描述:LED照明驱动器 6-Ch LED Backlt Drvr RoHS:否制造商:STMicroelectronics 输入电压:11.5 V to 23 V 工作频率: 最大电源电流:1.7 mA 输出电流: 最大工作温度: 安装风格:SMD/SMT 封装 / 箱体:SO-16N
MC34847	制造商:SPC Multicomp 功能描述:RECEPTACLE FREE 18WAY
MC34848EP	功能描述:LED照明驱动器 8 CHANNEL LED DRIVER RoHS:否制造商:STMicroelectronics 输入电压:11.5 V to 23 V 工作频率: 最大电源电流:1.7 mA 输出电流: 最大工作温度: 安装风格:SMD/SMT 封装 / 箱体:SO-16N
MC34848EPR2	功能描述:LED照明驱动器 8 CHANNEL LED DRIVER RoHS:否制造商:STMicroelectronics 输入电压:11.5 V to 23 V 工作频率: 最大电源电流:1.7 mA 输出电流: 最大工作温度: 安装风格:SMD/SMT 封装 / 箱体:SO-16N

发布紧急采购，3分钟左右您将得到回复。

采购需求

(若只采购一条型号，填写一行即可)

*型号	*数量	厂商	批号	封装

添加更多采购

我的联系方式

*

*

*