收藏本站
参数资料
型号: MIC3230YTSE
厂商: Micrel Inc
文件页数: 14/19页
文件大小: 0K
描述: IC LED DRVR HP CONS CURR 16TSSOP
标准包装: 94
恒定电流:
拓扑: PWM,升压(升压)
输出数: 1
内部驱动器:
类型 - 主要: 通用
频率: 100kHz ~ 1MHz
电源电压: 6 V ~ 45 V
安装类型: 表面贴装
封装/外壳: 16-TSSOP(0.173",4.40mm)裸露焊盘
供应商设备封装: 16-EPAD TSSOP
包装: 管件
工作温度: -40°C ~ 125°C
产品目录页面: 1082 (CN2011-ZH PDF)
其它名称: 576-3402-5
0 . 45 = I RAMP × R SLC × D + I L _ pk Limit × R CS
V OUT ? V IN MIN ) × R CS
R SLC =
Eq. (13)
L = IN
= 43 μ H
12 V × 0 . 56 × 2 μ s
R CS =
Eq. (13a)
I in _ PP =
V IN _ nom × D nom × T 12 v × 0 . 56 × 2 us
R CS =
( 28 v ? 8 v ) × ( 0 . 50 ) + 1 . 9 A = 179 m Ω
( 28 ? 8 ) × 150 m Ω
R SLC = = 511 Ω
( I IN _ RMS _ max ) 2 ? ( I IN 12 PP )
Eq. (13b)
I IN _ AVE _ max =
Micrel, Inc.
(see the current waveforms in Figure 5).
It can be difficult to find large inductor values with high
saturation currents in a surface mount package. Due to
this, the percentage of the ripple current may be limited
by the available inductor. It is recommended to operate
in the continuous conduction mode. The selection of L
described here is for continuous conduction mode.
V × D × T
I in _ PP
Using the nominal values, we get:
L =
0 . 31 A
Select the next higher standard inductor value of 47μH.
Going back and calculating the actual ripple current
gives:
= = 0 . 29 A PP
L 47 uh
The average input current is different than the RMS input
current because of the ripple current. If the ripple current
is low, then the average input current nearly equals the
RMS input current. In the case where the average input
current is different than the RMS, Equation 10 shows the
following:
2
_
MIC3230/1/2
Eq. (14a)
To calculate the value of the slope compensation resistance,
R SLC , we can use Equation 5:
MAX
L × 250 μ A × F SW
First we must calculate R CS , which is given below in
Equation 15:
Eq. (15) 0 . 45
( VOUT MAX ? VIN MIN ) × D max + I L _ pk Limit
L × F SW
Therefore;
0 . 45
47 μ H × 500 kHz
Using a standard value 150m ? resistor for R CS , we obtain
the following for R SLC :
47 μ H × 250 μ A × 500 kHz
Use the next higher standard value if this not a standard
value. In this example 511 ? is a standard value.
Check: Because we must use a standard value for Rcs and
R SLC; I L _ pk Limit may be set at a different level (if the calculated
value isn’t a standard value) and we must calculate the
actual I L _ pk Limit value (remember I L _ pk Limit is the same as
I IN _ AVE _ max =
( 1 . 64 ) 2 ? ( 0 . 29 ) 2 / 12 ≈ 1 . 64 A
I in _ pk Limit ).
I in _ pk Limit =
I in _ actual Limit =
= 2 . 34 A
Eq. (13c) P INDUCTOR = I in _ RMS _ max × DCR
The Maximum Peak input current I L_PK can found using
equation 11:
I L _ PK _ max = I IN _ AVE _ max + 0 . 5 × I L _ PP _ max = 1 . 78 A
The saturation current (I SAT ) at the highest operating
temperature of the inductor must be rated higher than
this.
The power dissipated in the inductor is:
2
Current Limit and Slope Compensation
Having calculated the I L_pk above, We can set the current
limit 20% above this maximum value:
I L _ pk Limit = 1 . 2 × 1 . 6 A = 1 . 9 A
The internal current limit comparator reference is set at
0.45V, therefore when V IS _ PIN = 0 . 45 , the IC enters
current limit.
Eq. (14) 0 . 45 = ( V A PK + Vcs PK )
Where V A PK is the peak of the V A waveform and
Vcs PK is the peak of the Vcs waveform
Rearranging Equation 14a to solve for I L _ pk Limit :
( 0 .45 ? I RAMP × R SLC × D )
R CS
( 0 . 45 ? 250 ua × 511 × 0 . 75 )
. 150
This is higher than the initial 1 . 2 × I L _ PK _ max = 1 . 9 A limit
because we have to use standard values for R CS and for
R SLC . If I in _ actual Limit is too high than use a higher value for
R CS . The calculated value of R CS for a 1.9A current limit was
179m ? . In this example, we have chosen a lower value
which results in a higher current limit. If we use a higher
standard value the current limit will have a lower value. The
designer does not have the same choices for small valued
resistors as with larger valued resistors. The choices differ
from resistor manufacturers. If too large a current sense
resistor is selected, the maximum output power may not be
able to be achieved at low input line voltage levels. Make
sure the inductor will not saturate at the actual current limit
I in _ actual Limit .
Perform a check at I IN =2.34Apk.
V IS _ PIN = 250 μ A × ( 0 . 78 ) × 511 Ω + 2 . 34 A × 150 m Ω = 0 . 45 V
March 2011
14
M9999-030311-D
相关PDF资料
PDF描述
XRP7604EDB-F IC CONV PWM STP-DWN BUCK 8SOIC
GMM02DRYN-S13 CONN EDGECARD 4POS .156 EXTEND
VE-JTF-CW-S CONVERTER MOD DC/DC 72V 100W
GEM28DRUN CONN EDGECARD 56POS DIP .156 SLD
TAJV107K025A CAP TANT 100UF 25V 10% 2924
相关代理商/技术参数
参数描述
MIC3230YTSE TR 功能描述:LED照明驱动器 Boost Driver Controller for High Power LEDs 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
MIC3231YML 制造商:MICREL 制造商全称:Micrel Semiconductor 功能描述:Constant Current Boost Controller for Driving High Power LEDs
MIC3231YML TR 功能描述:LED照明驱动器 Boost Driver Controller with Dither for High Power LEDs 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
MIC3231YML-TR 功能描述:LED 驱动器 IC 1 输出 DC DC 控制器 升压(升压) PWM 调光 12-MLF?(4x4) 制造商:microchip technology 系列:- 包装:剪切带(CT) 零件状态:停产 类型:DC DC 控制器 拓扑:升压(升压) 内部开关:无 输出数:1 电压 - 供电(最低):6V 电压 -?供电(最高):45V 电压 - 输出:- 电流 - 输出/通道:- 频率:100kHz ~ 1MHz 调光:PWM 应用:照明 工作温度:-40°C ~ 125°C (TJ) 安装类型:表面贴装 封装/外壳:12-VFDFN 裸焊盘,12-MLF? 供应商器件封装:12-MLF?(4x4) 标准包装:1
MIC3231YTSE 功能描述:LED照明驱动器 Boost Driver Controller with Dither for High Power LEDs 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)

发布成功!您可以继续发布采购。也可以进入我的后台,查看报价

发布成功!您可以继续发布采购。也可以进入我的后台,查看报价

*型号 *数量 厂商 批号 封装
添加更多采购

我的联系方式

*
*
*