Datasheet> 器件分类 > 无源元件> 振荡器> SIT3521AC-1C32810G340.000000T

文档预览

SIT3521AC-1C32810G340.000000T: 产品描述LVPECL Output Clock Oscillator, 340MHz Nom, QFN, 10 PIN; 产品类别无源元件振荡器; 文件大小3MB，共47页; 制造商SiTime; 标准

下载文档详细参数全文预览

SIT3521AC-1C32810G340.000000T概述

LVPECL Output Clock Oscillator, 340MHz Nom, QFN, 10 PIN

SIT3521AC-1C32810G340.000000T规格参数

参数名称	属性值
是否Rohs认证	符合
厂商名称	SiTime
包装说明	LCC10,.12X.2,50/40
Reach Compliance Code	unknow
其他特性	ENABLE/DISABLE FUNCTION; COMPLEMENTARY OUTPUT
最长下降时间	0.29 ns
频率调整-机械	NO
频率稳定性	50%
JESD-609代码	e4
安装特点	SURFACE MOUNT
端子数量	10
标称工作频率	340 MHz
最高工作温度	70 °C
最低工作温度	-20 °C
振荡器类型	LVPECL
输出负载	50 OHM
封装等效代码	LCC10,.12X.2,50/40
物理尺寸	5.0mm x 3.2mm x 0.9mm
最长上升时间	0.29 ns
最大供电电压	3.08 V
最小供电电压	2.52 V
标称供电电压	2.8 V
表面贴装	YES
最大对称度	55/45 %
端子面层	Nickel/Palladium/Gold (Ni/Pd/Au)

SIT3521AC-1C32810G340.000000T文档预览

SiT3521

Description

PRELIMINARY

1 to 340 MHz Elite Platform™ I

C/SPI Programmable Oscillator

Features



The

SiT3521

is an ultra-low jitter, user programmable

oscillator which offers the system designer great flexibility

and functionality.

The device supports two in-system programming options

after powering up at a default, factory programmed startup

frequency:



Any-frequency mode where the clock output can be re-

programmed to any frequency between 1 MHz and

340 MHz in 1 Hz steps

Digitally controlled oscillator (DCO) mode where the

clock output can be steered or pulled by up to

±3200

ppm with 5 to 94 ppt (parts per trillion) resolution.



The device’s default start-up frequency is specified in the

ordering code. User programming of the device is achieved

via I C or SPI. Up to 16 I C addresses can be specified by

the user either as a factory programmable option or via

hardware pins, enabling the device to share the I C with

other I C devices.

The SiT3521 utilizes SiTime’s unique DualMEMS™

temperature sensing and TurboCompensation™ technology

to deliver exceptional dynamic performance:



Programmable frequencies (factory or via I C/SPI)

from 1 MHz to 340 MHz

Digital frequency pulling (DCO) via I C/SPI



Output frequency pulling with perfect pull linearity



13 programmable pull range options to

±3200

ppm



Frequency pull resolution as low as 5 ppt (0.005 ppb)

0.21 ps typical integrated phase jitter (12 kHz to 20 MHz)

Integrated LDO for on-chip power supply noise filtering

0.02 ps/mV PSNR

-40°C to 105°C operating temperature

LVPECL, LVDS, or HCSL outputs



Programmable LVPECL, LVDS Swing



LVDS Common Mode Voltage Control

RoHS and REACH compliant, Pb-free, Halogen-free

and Antimony-free

Applications



Resistant to airflow and thermal shock

Resistant to shock and vibration

Superior power supply noise rejection

Combined with wide frequency range and user

programmability, this device is ideal for telecom, networking

and industrial applications that require a variety of

frequencies and operate in noisy environment.

Ethernet: 1/10/40/100/400 Gbps

G.fast and xDSL

Optical Transport: SONET/SDH, OTN

Clock and data recovery

Processor over-clocking

Low jitter clock generation

Server, storage, datacenter

Test and measurement

Broadcasting

Block Diagram

Package Pinout

(10-Lead QFN, 5.0 x 3.2 mm)

A/ K

SD C L

OE / NC

GND

VDD

OUT-

OUT+

A1 A0

/N /N

C/ C/

M SS

Figure 1. SiT3521 Block Diagram

Figure 2. Pin Assignments (Top view)

(Refer to

Table 14

for Pin Descriptions)

Rev 0.991

April 25, 2020

www.sitime.com

SiT3521

1 to 340 MHz Elite™ I

C/SPI Programmable Oscillator

Ordering Information

PRELIMINARY

SiT3521 AC -1C133 1 GG156.250000T

Part Family

“SiT3521”

12 mm Tape & Reel, 3ku reel

12 mm Tape & Reel, 1ku reel

[2]

Revision Letter

“A” is the revision of Silicon

Frequency

1.000000 to 340. 000000 MHz

Temperature Range

“C” : Extended Commercial, -20 to 70°C

“ I ” : Industrial, -40 to 85°C

“E” : Extended Industrial, -40 to 105°C

[1]

Signaling Type

“1”: LVPECL

“2”: LVDS

“4”: HCSL

DCXO Pull Range

“M”

“B”

“C”

“E”

“F”

“G”

“H”

“X”

“L”

“Y”

“S”

“Z”

“U”

± 25 ppm

± 50 ppm

± 80 ppm

±100 ppm

±125 ppm

±150 ppm

±200 ppm

±400 ppm

± 600 ppm

±800 ppm

±1200 ppm

±1600 ppm

±3200 ppm

Package Size

“C”: 5.0 x 3.2 mm

Frequency Stability/Grade

“F”: ±10 ppm

“1”: ±20 ppm

“2”: ±25 ppm

“3”: ±50 ppm

Serial IF mode

“S”

: SPI mode

[1]

“0-G”

: I

C mode (See below)

I C Factory Programmable Addresses

“0-F” : I C Address factory programmed

Sets Bits 3: 0 of Device I

C address to

the Hex value of the ordering code .

When the I C address is factory

programmed using these codes ,

pin A0, A1 are NC

“G”: I

C address controlled by A0, A1 pins

A1:A0

C Address

1100000

1100010

1101000

1101010 (default)

Voltage Supply

“25” :

“28” :

“30” :

“33” :

2.5V

2.8V

3.0V

3.3V

±10%

OE Pin Control

“-”: OE under software Control.

Pin 1 and 2 are both NC.

“1”: Pin 1 OE, Pin 2 NC

“2”: Pin 1 NC, Pin 2 OE

Notes:

1. -40 to 105°C option available only for I

C operation.

2. Bulk is available for sampling only.

Rev 0.991

Page 2 of 47

www.sitime.com

SiT3521

1 to 340 MHz Elite™ I

C/SPI Programmable Oscillator

TABLE OF CONTENTS

PRELIMINARY

Description ................................................................................................................................................................................... 1

Features....................................................................................................................................................................................... 1

Applications ................................................................................................................................................................................. 1

Block Diagram ............................................................................................................................................................................. 1

Ordering Information .................................................................................................................................................................... 2

1 Electrical Characteristics ......................................................................................................................................................... 4

2 Device Configurations and Pin-outs ........................................................................................................................................ 9

3 Waveform Diagrams ............................................................................................................................................................. 11

4 Termination Diagrams ........................................................................................................................................................... 13

4.1. LVPECL .................................................................................................................................................................... 13

4.2. LVDS ........................................................................................................................................................................ 15

4.3. HCSL ........................................................................................................................................................................ 16

5 Test Circuit Diagrams ........................................................................................................................................................... 17

6 Architecture Overview ........................................................................................................................................................... 19

7 Functional Overview ............................................................................................................................................................. 19

7.1. User Programming Interface ..................................................................................................................................... 19

7.2. Start-up output frequency and signaling types .......................................................................................................... 19

7.3. In-system programmable options.............................................................................................................................. 19

8 In-system Programmable Functional Description.................................................................................................................. 20

8.1. Any-frequency function ............................................................................................................................................. 20

8.2. DCO Functional Description ..................................................................................................................................... 24

8.3. Pull Range, Absolute Pull Range .............................................................................................................................. 26

8.4. Software OE Functional Description ......................................................................................................................... 28

9 I C/SPI Control Registers...................................................................................................................................................... 29

9.1. Register Address: 0x00. DCO Frequency Control Least Significant Word (LSW) .................................................... 29

9.2. Register Address: 0x01. OE Control, DCO Frequency Control Most Significant Word (MSW) ................................. 30

9.3. Register Address: 0x02. DCO PULL RANGE CONTROL ........................................................................................ 31

9.4. Register Address: 0x03. Flac-N PLL Integer Value and Flac-N PLL Fraction MSW ................................................. 32

9.5. Register Address: 0x04. Flac-N PLL Fraction LSW .................................................................................................. 32

9.6. Register Address: 0x05. PostDiv, Driver Control ...................................................................................................... 33

9.7. Register Address: 0x06. mDriver, Driver Control ...................................................................................................... 34

10 I C Operation ........................................................................................................................................................................ 35

10.1. I C protocol ............................................................................................................................................................... 35

10.2. I C Timing Specification ............................................................................................................................................ 37

10.3. I C Device Address Modes ....................................................................................................................................... 38

11 SPI Operation ....................................................................................................................................................................... 39

Schematic Examples ................................................................................................................................................................. 42

Dimensions and Patterns ........................................................................................................................................................... 45

Additional Information ................................................................................................................................................................ 46

Revision History ......................................................................................................................................................................... 47

Rev 0.991

Page 3 of 47

www.sitime.com

SiT3521

1 to 340 MHz Elite™ I

C/SPI Programmable Oscillator

1 Electrical Characteristics

PRELIMINARY

All Min and Max limits in the Electrical Characteristics tables are specified over temperature and rated operating voltage with

standard output terminations shown in the termination diagrams. Typical values are at 25°C and nominal supply voltage.

Table 1. Electrical Characteristics – Common to LVPECL, LVDS and HCSL

Parameter

Output Frequency Range

Frequency Stability

Symbol

F_stab

Min.

-10

-20

-25

-50

First Year Aging

Operating Temperature Range

F_1y

T_use

–

-20

-40

Supply Voltage

Vdd

2.97

2.7

2.52

2.25

Input Voltage High

Input Voltage Low

Input Pull-up Impedance

Duty Cycle

Start-up Time

Output Enable/Disable Time –

Hardware control via OE pin

Output Enable/Disable Time –

Software control via I

C/SPI

VIH

VIL

Z_in

T_start

T_oe_hw

70%

–

Typ.

–

±1

–

3.3

3.0

2.8

2.5

–

100

–

Max.

340

+10

+20

+25

+50

–

+70

+85

+105

Supply Voltage

3.63

3.3

3.08

2.75

–

30%

–

3.0

3.8

Vdd

kΩ

µs

Measured from the time Vdd reaches its rated minimum value

Measured from the time OE pin reaches rated VIH and VIL to

the time clock pins reach 90% of swing and high-Z.

See

Figure 9

and

Figure 10

Measured from the time the last byte of command is

transmitted via I

C/SPI (reg1) to the time clock pins reach 90%

of swing and high-Z. See

Figure 30

and

Figure 31

OE pin

OE pin, logic high or logic low

Unit

MHz

ppm

°C

1 -year aging at 25°C

Extended Commercial

Industrial

Extended Industrial. Available only for I C operation, not SPI.

Condition

Factory or user programmable, accurate to 6 decimal places

Inclusive of initial tolerance, operating temperature, rated

power supply voltage and load variations.

Frequency Range

Frequency Stability

Temperature Range

Input Characteristics – OE Pin

Output Characteristics

Startup and Output Enable/Disable Timing

T_oe_sw

–

6.5

µs

Rev 0.991

Page 4 of 47

www.sitime.com

SiT3521

1 to 340 MHz Elite™ I

C/SPI Programmable Oscillator

Table 2. Electrical Characteristics – LVPECL Specific

Parameter

Symbol

Min.

Typ.

Max.

Unit

PRELIMINARY

Condition

Current Consumption

OE Disable Supply Current

Output Disable Leakage Current

Maximum Output Current

Idd

I_OE

I_leak

I_driver

–

0.15

–

A

Excluding Load Termination Current, Vdd = 3.3V or 2.5V

OE = Low

Maximum average current drawn from OUT+ or OUT-

Output Characteristics

Output High Voltage

Output Low Voltage

Output Differential Voltage Swing

Rise/Fall Time

VOH

VOL

V_Swing

Tr, Tf

Vdd - 1.1V

Vdd - 1.9V

1.2

–

1.6

225

Vdd - 0.7V

Vdd - 1.5V

2.0

290

Jitter

RMS Phase Jitter (random) –

DCO Mode Only

T_phj

–

RMS Phase Jitter (random) –

Any-frequency Mode Only

T_phj

–

RMS Period Jitter

[3]

Note:

3. Measured according to JESD65B.

T_jitt

–

0.225

0.1

0.225

0.11

0.340

0.14

0.340

0.15

1.6

f = 156.25 MHz, Integration bandwidth = 12 kHz to 20 MHz,

all Vdd levels

f = 156.25, IEEE802.3-2005 10 GbE jitter mask integration

bandwidth = 1.875 MHz to 20 MHz, all Vdd levels

f = 156.25 MHz, Integration bandwidth = 12 kHz to 20 MHz,

all Vdd levels

f = 156.25, IEEE802.3-2005 10 GbE jitter mask integration

bandwidth = 1.875 MHz to 20 MHz, all Vdd levels

f = 100, 156.25 or 212.5 MHz, Vdd = 3.3V or 2.5V

See

Figure 5

See

Figure 5

See

Figure 6

20% to 80%, see

Figure 6

Table 3. Electrical Characteristics – LVDS Specific

Parameter

Symbol

Min.

Typ.

Max.

Unit

Condition

Current Consumption

OE Disable Supply Current

Output Disable Leakage Current

Idd

I_OE

I_leak

–

0.15

–

A

Excluding Load Termination Current, Vdd = 3.3V or 2.5V

OE = Low

Output Characteristics

Differential Output Voltage

Delta VOD

Offset Voltage

Delta VOS

Rise/Fall Time

VOD

ΔVOD

VOS

ΔVOS

Tr, Tf

250

–

1.125

–

400

455

1.375

470

Jitter

RMS Phase Jitter (random) –

DCO Mode Only

T_phj

–

RMS Phase Jitter (random) –

Any-frequency Mode Only

T_phj

–

RMS Period Jitter

[4]

Note:

4. Measured according to JESD65B.

T_jitt

–

0.21

0.1

0.21

0.1

0.275

0.12

0.367

0.12

1.6

f = 156.25 MHz, Integration bandwidth = 12 kHz to 20 MHz,

all Vdd levels

f = 156.25, IEEE802.3-2005 10 GbE jitter mask integration

bandwidth = 1.875 MHz to 20 MHz, all Vdd levels

f = 156.25 MHz, Integration bandwidth = 12 kHz to 20 MHz,

all Vdd levels

f = 156.25, IEEE802.3-2005 10 GbE jitter mask integration

bandwidth = 1.875 MHz to 20 MHz, all Vdd levels

f = 100, 156.25 or 212.5 MHz, Vdd = 3.3V or 2.5V

f = 156.25MHz See

Figure 7

See

Figure 7

See

Figure 7

See

Figure 7

Measured with 2 pF capacitive loading to GND, 20% to 80%,

see

Figure 8

Rev 0.991

Page 5 of 47

www.sitime.com

查看更多（仅显示前5页内容，查看全部内容请下载文档。）>

推荐资源

eboot中断: #define pISR (*(unsigned *)(0x30000000+0x18)) //#define pISR (*(unsigned *)(0x00000000+0x18)) 这里应该填什么？ // Virtual Address 0x0 is mapped to 0x30000000, ISR Address is V ......; laowen_110 嵌入式系统

activesync怎样手工给它添加驱动？: 如题,我安装好wince5之前就按好了activesync，结果它立马就连接了，我当时还不知道怎么操作，就稀里糊涂的也没有连上，现在我再次插上开发板(mini2440)的时候，它就没有提示我要安装驱动程 ......; yuhongcai11 嵌入式系统

高级无源射频工程师、有源专家: 有源专家（总监级别）岗位职责：1. 负责制定有源产品开发方向，指导有源产品的设计框架和指标设计细节；2. 协调有源与无源部分的匹配，指导产品设计与系统、基站之间的匹配。任职资格：1. 全 ......; 52zhibang 求职招聘

关于CPU启动的问题: 在MIPS平台下，WINCE操作系统，CPU启动的时候，在OAL层还没初始化到OEM的时候已经完成了串口的初始化，在OEM初始化中最开始的打印信息为“+OEMInit”，我想问一下，“Windows CE Kernel for MIP ......; 独步狼嵌入式系统

Freescale HC08单片机？？？: 我专业是嵌入式，开的一门课是《嵌入式技术基础与实践》，里面学的是HC08单片机。书，实验开发箱都是苏大自家做的。毕业设计老师要用HC08单片机做，可是资料很少，图书馆都没找到……… 有多少 ......; yelanghijie 嵌入式系统

反激电源变压器设计步骤: 本帖最后由 qwqwqw2088 于 2016-5-12 09:44 编辑先说明两个定义： 1.Vor定义为反射电压。 2.Krp定义为电流的波峰比，即峰峰值：峰值。反激是由Buck-Boost电路演变而来，最苛刻的点为最 ......; qwqwqw2088 模拟与混合信号

POSCO Future M推出高端和标准电动汽车正极材料

据外媒报道，二次电池材料公司POSCO Future M宣布，已成功开发出两种针对高端和标准电动汽车市场的试验（原型）正极材料。图片来源： POSCO Future M “超高镍正极材料”专为高端电动汽车设计，将高镍正极材料中的镍含量从现有的80%提升至95%以上。该材料能量密度高，可最大程度延长电动汽车的续航里程。该公司的目标是向美国和欧洲等发达市场的高端电动汽车和城市空中交...[详细]
机器人，引爆激光雷达

机器人成为激光雷达的“第二增长曲线”。就在激光雷达还在汽车领域和“纯视觉路线”的对手Battle之际，一个领域却点爆了对它的需求。 8月15日，禾赛科技（HS AI ）宣布了两个消息。一是公布了2025年第二季度未经审计的财务数据，其中最大的亮点是当季净利润突破4400万元，远超GAAP层面盈利转正目标。而整个第二季度，禾赛实现营收7.1亿元，同比增长超50%。值得“敲...[详细]
全新MG4半固态电池版已上工信部公告，年内批量交付

日前，全新MG4正式登陆工信部新车公告，其中的全新MG4半固态电池版，解决了电池在低温性能与安全上的技术瓶颈，为行业带来了新的技术突破。其搭载的半固态电池通过底层材料技术创新，液态电解质含量降至5%，已接近准固态电池水平，从根本上解决电池自燃隐患。本次公告，标志着半固态电池技术正式步入商业化应用新阶段。 8月29日，全新MG4将正式上市，其半固态电池版也将同步发布价格，预计年内批量交付。半固...[详细]
基于LED光数据传输的温度实时显示系统

　　本文提出了以京微雅格低功耗FPGA HR(黄河)系列为主控制器，以温度传感器，LED灯，光频转换器，LCD屏等为外围电路的基于LED光数据传输的温度实时传输及显示方案，实现了可靠的温度值实时传输和显示。　　1. 系统功能介绍　　本系统主要包括CME-HR03 FPGA，温度传感器，光频转换器及LCD显示屏几个部分，其实现框图如下所示：　　本系统中，首先由温度传感器经IIC接口将...[详细]
是德科技研究发现：人工智能发展速度已超越基础设施准备程度

随着AI在各个行业中加速发展，对数据中心基础设施的需求也在迅速增长是德科技与Heavy Reading合作发布了《超越瓶颈：2025年AI集群网络报告》，探讨运营商如何演进以适应人工智能（AI）工作负载的规模和速度。报告显示近九成（89%）电信和云服务提供商计划扩大或维持AI基础设施投资，其中前三大增长因素分别为云集成（51%）、更高速的GPU（49%）和高速网络升级（45%）。 ...[详细]
电动汽车以什么样的充电方式才是最合适的

电动汽车续航里程越来越长，普及率越来越高。电动汽车充电有两种方式慢充和快充,哪一种方式最合适呢？慢充，就是采用交流220V或三相380V（普通家用照明电源或动力电源）使用输出功率为5kW左右的充电器给电动汽车充电。快充就是利用充电桩进行直流充电，插头接电动汽车的直流充电口进行充电，根据充电桩的功率可达30KW~60KW。电动汽车是以电动机动力行驶的汽车，而车载蓄电池是为电动机提供电能的核心...[详细]
全球电动汽车电池供需失衡：供应或达需求三倍以上

据日经新闻报道，调查发现，由于电动汽车需求降温，全球电动汽车电池供应量有望达到需求量的三倍以上，这为日本和美国等国家建立本土生产的举措带来了阻力。图片来源：宁德时代基于标普全球移动出行（S&P Global Mobility）的数据，日经新闻指出，电动汽车电池生产设施的总年产能预计将达到3,930 GWh，而需求量预计为1,161 GWh。到2026年，电动汽车电池供...[详细]
比亚迪发布新一代「灵充」充电桩，3.5kW/7kW双版本兼容主流车型

8月21日，比亚迪宣布推出新一代“小白桩”产品——「灵充」充电桩，并已全面开放销售。这款充电桩采用了更加圆润的设计，提供3.5kW和7kW两种版本，支持即插即充或NFC刷卡启动，同时手机可复制卡片信息，实现一碰即启动的便捷操作。「灵充」充电桩深度兼容主流新能源汽车品牌，用户无需为不同车型寻找专用充电桩，同时提供超长质保服务。小智版还额外赠送6年流量桩体防伪码，用户可通过扫码辨别真伪。在安全...[详细]
10000台！这家公司拿下全球首个人形机器人最大单笔订单

天太机器人官微8月20日晚间发布消息，天太机器人有限公司8月20日与山东未来机器人技术有限公司、山东未来数据科技、港仔机器人集团等战略合作伙伴，共同签署全球首个具身智能人形机器人10000台订单，这是全球人形机器人行业诞生以来数量最大的单笔订单。这意味着，曾被视作“科幻”的人形机器人，正式走出实验室、跨越概念阶段，作为一种可量产、可交付、可解决实际问题的生产力工具，浩浩荡荡地涌入现实世界的...[详细]
探索当今TWS耳机的混合设计配置及OEM面临的工程挑战

消费者对高端聆听体验的需求推动无线耳机市场近年来快速迭代。混合设计在每只耳机中采用两种驱动单元，以提升音质、功能和佩戴舒适度。随着原始设备制造商（OEM）力求超越消费者预期并在市场中保持竞争力，这类设计正日益普及。真无线立体声（TWS）耳机领域正加速采用混合设计。混合方案的兴起促使 TWS 耳机经历重大技术重构，不仅影响制造商的产品架构，更为消费者带来显著优化的声音体验。本文将概述当今 T...[详细]
瑞萨电子全新超低功耗RA4C1 MCU具备高级安全性和专用外设集

瑞萨电子全新超低功耗RA4C1 MCU具备高级安全性和专用外设集，是表计应用及其他应用的理想选择全新产品满足DLMS Suite2表计应用安全法规，提供丰富的通信选项、电容式触摸界面，以及支持软件更新的双区闪存 2025 年 8 月 21 日，中国北京讯 - 全球半导体解决方案供应商瑞萨电子今日宣布推出基于80MHz Arm ® Cortex ® -M33处理器的RA4C1微控制器...[详细]
了解您的可穿戴设备的图形内存需求

　　高清媒体消费正在经历双重增长，一是消费者数量的增加，二是向更加高清的内容过渡。增长动力来自日益普及、速度越来越快的互联网接入服务以及移动设备(手机、平板电脑、可穿戴设备等)的爆炸式增长。因此，当今的很多可穿戴设备都能处理高清媒体的消费。　　即使按照最保守的估计，到2020年，市场对物联网(IoT) 和可穿戴设备的需求将增长三倍。这意味着全球将有500亿件设备。这将催生对新一代显示器驱动...[详细]
stm32单片机时钟

1 引言：# 单片机（Microcontrollers），采用超大规模集成电路技术把具有数据处理能力的中央处理器CPU、随机存储器RAM、只读存储器ROM、多种I/O口和中断系统、定时器/计数器等功能（可能还包括显示驱动电路、脉宽调制电路、模拟多路转换器、A/D转换器等电路）集成到一块硅片上构成的一个小而完善的微型计算机系统，在工业控制领域广泛应用。单片机时钟可以说如同人的心脏那样重要，我们在...[详细]
汽车传动轴的作用

　　当我们拿到一件陌生的物品，首先想知道的就是它到底是干什么的？传动轴、顾名思义传递动力的轴、它是将发动机输出的经过变速箱减速增扭后的动力传递到汽车驱动轮的传力介质、没有它靠什么来驱动车轮旋转呢、车轮不旋转车怎么跑呢？下面就和电动邦小编一起围观汽车传动轴的作用吧。　　汽车传动轴作为汽车传动系统中的传递动力的重要部件，它可以与变速箱、驱动桥一起将发动机的动力传递给车轮，使汽车产生驱动力。通常...[详细]
铜编织线软连接和铜绞线软连接哪个好

铜编织线软连接和铜绞线软连接哪个好-在选择铜线软连接的时候，人们总会纠结于是用铜编织线软连接还是铜绞线软连接，两者除了外观上的区别之外，使用过程中也表现出了不一样的特点，但好在它们的作用是一样的，所以应用对象基本都是相似的。铜编织线软连接我们先来了解铜编织线软连接，它是经多根细圆铜丝经过交叉编织成一条扁平的铜编织带，形状是扁平带状。而铜绞线虽然也是由多根细圆丝加工而成，但他不是交叉编织...[详细]

器件捷径: S0 S1 S2 S3 S4 S5 S6 S7 S8 S9 SA SB SC SD SE SF SG SH SI SJ SK SL SM SN SO SP SQ SR SS ST SU SV SW SX SY SZ T0 T1 T2 T3 T4 T5 T6 T7 T8 T9 TA TB TC TD TE TF TG TH TI TJ TK TL TM TN TO TP TQ TR TS TT TU TV TW TX TY TZ U0 U1 U2 U3 U4 U6 U7 U8 UA UB UC UD UE UF UG UH UI UJ UK UL UM UN UP UQ UR US UT UU UV UW UX UZ V0 V1 V2 V3 V4 V5 V6 V7 V8 V9 VA VB VC VD VE VF VG VH VI VJ VK VL VM VN VO VP VQ VR VS VT VU VV VW VX VY VZ W0 W1 W2 W3 W4 W5 W6 W7 W8 W9 WA WB WC WD WE WF WG WH WI WJ WK WL WM WN WO WP WR WS WT WU WV WW WY X0 X1 X2 X3 X4 X5 X7 X8 X9 XA XB XC XD XE XF XG XH XK XL XM XN XO XP XQ XR XS XT XU XV XW XX XY XZ Y0 Y1 Y2 Y4 Y5 Y6 Y9 YA YB YC YD YE YF YG YH YK YL YM YN YP YQ YR YS YT YX Z0 Z1 Z2 Z3 Z4 Z5 Z6 Z8 ZA ZB ZC ZD ZE ZF ZG ZH ZJ ZL ZM ZN ZP ZR ZS ZT ZU ZV ZW ZX ZY

热门器件

开源项目推荐更多

热门活动更多

热门文章更多

技术资料推荐更多