久久88色综合色鬼,欧美丰满熟妇XXXX性

您好，
買賣IC網(wǎng)歡迎您。
請登錄
免費注冊

您現(xiàn)在的位置：買賣IC網(wǎng) > PDF目錄365564 > SI9961 (Vishay Intertechnology,Inc.) 12-V Voice Coil Motor Driver PDF資料下載

參數(shù)資料

型號：	SI9961
廠商：	Vishay Intertechnology,Inc.
元件分類：	基準電壓源/電流源
英文描述：	12-V Voice Coil Motor Driver
中文描述：	12 V的音圈電機驅(qū)動器
文件頁數(shù)：	6/8頁
文件大?。?/td>	69K
代理商：	SI9961

第1頁第2頁第3頁第4頁第5頁當前第6頁第7頁第8頁

Si9961

Vishay Siliconix

www.vishay.com

Document Number: 70014

S-20883

—

Rev. G, 24-Jun-02

Frequency Compensation:

The VCM transconductance (in siemens) of this simplified

case may be expressed in the s (Laplace) plane as:

Where R

= VCM resistance in ohms

= VCM inductance in henrys

s is the Laplace operator

In this case, the transconductance pole is at

–

Rv/Lv. It is

desirable to cancel this pole in the interest of stability. To do

this, a compensation amplifier is cascaded with the VCM and

its driver. The transfer function of this amplifier is:

Where R

Compensation amplifier feedback

resistor in ohms

Compensation amplifier feedback

capacitor in farads

Compensation amplifier and driver

voltage gain at high frequency

If R

x C

is set equal to L

, then the combined open loop

transconductance in siemens becomes:

In this case, the transconductance has a single pole at the

origin. If this open loop transfer is closed with a

transimpedance amplifier having a gain of B ohms, the

resultant closed loop transconducatance stage has the

transfer function (in siemens) of:

Where B = Current feedback transimpedence amplifier gain in

ohms.

The entire transconductance now contains only a single pole

–

A*B/Lv. A and B are chosen to be considerably higher than

the servo bandwidth, to avoid undue phase margin reduction.

As a typical example, in the referenced schematic, assume

that Rsa and Rsb = 0.5 , R

= R

= 10 k , VCM inductance

(Lv) = 1.5 mH, VCM resistance (Rv) = 15 . Hence:

1.5 mH

16 x R

/10000

/(R

x R

) = 100 x 10

–

farads

Gain Optimization:

There are three things to consider when optimizing the gain (A)

above. The first is servo bandwidth. The main criterion here is

to avoid having the transconductance amplifier cause an

undue loss of phase margin in the overall servo (mechanical

+ electrical + firmware) loop. The second is to avoid confirguing

a bandwidth that is more than required in view of noise and

stability considerations. The third is to keep the voltage output

waveform overshoot to a level that will not cause

cross-conduction of the output FETs.

The first two problems can be considered together. Let us

assume a disk drive with a spindle RPM of 4400 and with

50 servo sectors per track. The sample rate is therefore:

440

This is a sample frequency of 3667 Hz

As a rule of thumb, the open loop unity gain crossover

frequency of the entire servo (mechanical + electrical +

firmware) loop should be less than 1/10 of the sample

frequency. In this example, the servo open loop unity gain

crossover frequency would be less than 367 Hz. If we allow

only a 10 degradation in phase margin due to the

transconductance amplifier, then a phase lag of 10 at 367 Hz

is acceptable. This results in a 3-dB point in the

transconductance at :

3db

367

tan(10)

or a 3-dB point in the transconductance at 2081 Hz.

The pole in the closed loop transconductance (

–

A * B / Lv)

should then be 2081 * 2 * = 13075. This means that A = 9.8.

From the above equation for A, R

= 6.2 k . This sets the

minimum gain limit governed by the servo bandwidth

requirements. The gain should not be much greater than this,

since increased noise will degrade the servo response.

The third problem, keeping the transconductance amplifier

voltage output wave form overshoot to a level that will not

cause the wrong output FETs to conduct, can be evaluated by

deriving the voltage transfer function of the closed loop

transconductance amplifier from input voltage to output

voltage (Vin to output A and B on the reference schematic).

This is :

Where p =

1/R

x C

) or R

Comp amplifier

zero/VCM pole

A x B/L

closed loop pole

x =

相關(guān)PDF資料	PDF描述
Si9976	N-Channel Half-Bridge Driver
SI9976DY	N-Channel Half-Bridge Driver
SI9978	Configurable H-Bridge Driver
SI9978DW	Configurable H-Bridge Driver
SI9978DW-T1	Configurable H-Bridge Driver

相關(guān)代理商/技術(shù)參數(shù)	參數(shù)描述
SI9961A	制造商:VISHAY 制造商全稱:Vishay Siliconix 功能描述:12-V Voice Coil Motor Driver
SI9961ACY	功能描述:馬達/運動/點火控制器和驅(qū)動器 Voice Coil Driver RoHS:否制造商:STMicroelectronics 產(chǎn)品:Stepper Motor Controllers / Drivers 類型:2 Phase Stepper Motor Driver 工作電源電壓:8 V to 45 V 電源電流:0.5 mA 工作溫度:- 25 C to + 125 C 安裝風格:SMD/SMT 封裝 / 箱體:HTSSOP-28 封裝:Tube
SI9961ACY-E3	功能描述:馬達/運動/點火控制器和驅(qū)動器 Voice Coil Driver RoHS:否制造商:STMicroelectronics 產(chǎn)品:Stepper Motor Controllers / Drivers 類型:2 Phase Stepper Motor Driver 工作電源電壓:8 V to 45 V 電源電流:0.5 mA 工作溫度:- 25 C to + 125 C 安裝風格:SMD/SMT 封裝 / 箱體:HTSSOP-28 封裝:Tube
SI9961ACY-T1	功能描述:馬達/運動/點火控制器和驅(qū)動器 Voice Coil Driver RoHS:否制造商:STMicroelectronics 產(chǎn)品:Stepper Motor Controllers / Drivers 類型:2 Phase Stepper Motor Driver 工作電源電壓:8 V to 45 V 電源電流:0.5 mA 工作溫度:- 25 C to + 125 C 安裝風格:SMD/SMT 封裝 / 箱體:HTSSOP-28 封裝:Tube
SI9961ACY-T1-E3	功能描述:馬達/運動/點火控制器和驅(qū)動器 Voice Coil Driver RoHS:否制造商:STMicroelectronics 產(chǎn)品:Stepper Motor Controllers / Drivers 類型:2 Phase Stepper Motor Driver 工作電源電壓:8 V to 45 V 電源電流:0.5 mA 工作溫度:- 25 C to + 125 C 安裝風格:SMD/SMT 封裝 / 箱體:HTSSOP-28 封裝:Tube

發(fā)布緊急采購，3分鐘左右您將得到回復。

采購需求

(若只采購一條型號，填寫一行即可)

*型號	*數(shù)量	廠商	批號	封裝

添加更多采購

采購需求

發(fā)布成功！您可以繼續(xù)發(fā)布采購。也可以進入我的后臺，查看報價

發(fā)布成功！您可以繼續(xù)發(fā)布采購。也可以進入我的后臺，查看報價

我的聯(lián)系方式

采購需求

發(fā)布成功！您可以繼續(xù)發(fā)布采購。也可以進入我的后臺，查看報價

發(fā)布成功！您可以繼續(xù)發(fā)布采購。也可以進入我的后臺，查看報價

我的聯(lián)系方式

發(fā)布成功！您可以繼續(xù)發(fā)布采購。也可以進入我的后臺，查看報價

發(fā)布成功！您可以繼續(xù)發(fā)布采購。也可以進入我的后臺，查看報價