自动化专业英语重点

第一篇：自动化专业英语重点

欧姆定律

Ohm’s law states that the voltage across the resistor is equal to the current through the resistor multiplied by the value of the resistance.法拉第定律

Faraday’s states that the voltage across the inductor is proportional to the rate of change with time of the current through the inductor.基尔霍夫第一定律

Kirchhoff’s first law states that the algebraic sum of the voltages around a closed loop is 0,or,in any closed loop, sum of the voltage rises must equal the sum of voltage drops.运放

The first law states that in normal op-amp circuits we may assume that the voltage difference between the input terminals is zero, that is, U+=U-.The second law states that in normal op-amp circuits both of the input currents may be assumed to be zero: I+=I-电路理论 theory of circuit

模拟电子技术analog electronics technology

数字电子技术digital electronics technology

电力电子技术power electronics technology

电磁场electromagnetic field

电机与拖动electric motor and electric drive

电力拖动自动控制系统electric drive automatic control system 自动控制理论automatic control theory

现代控制理论modern control theory

智能控制intelligent control

微机原理principle of microcomputer

计算机接口技术computer interface technology

计算机控制技术computer control technology

自动调节装置automatic regulators

过程控制系统process control system

过程检测及仪表process measurement and instrument

单片机原理与应用principle and application of single-chip computer 可编程序控制器系统programmable logical controller system 现场总线技术fieldbus technology

嵌入式系统embedded system

供电技术power supplying technology

计算机仿真computer simulation

信号分析与处理signal analyzing and processing

集散控制系统distributed control system

楼宇自动化building automation

机器人学robotics

GTOgate turn-off thyristor门极可关断晶闸管 GJTbipolar junction transistor双极结型晶体管 SCR

第二篇：自动化专业英语 考试 重点单词

（一）单词英译汉

circuit components电路元件root mean square values 均方根值 Conductor导体effective value有效值

Wire导线sinusoidal time function正弦时间函数 Circuit diagram电路图circuit parameters：电路参数 Voltage drop电压降Time-invariant： 时不变的 Non-linear characteristic非线性特性Storage battery：蓄电池 ideal source理想电源Load characteristic：负载特性 ideal voltage source理想电压源Terminal voltage：端电压

ideal current source理想电流源Active circuit elements有源电路元件 potential电位

series and parallel equivalent circuit 串并联等值电路

internal resistance 内阻

complex number 复数

vector 向量

absolute value 绝对值

complex peak value 复数幅值

rotating vector旋转变量

logic circuit 逻辑电路

digital circuit 数字电路

chance variable 随机变量

decimal number 十进制数

logic condition 逻辑状态

output lead 输出端

logic OR function 逻辑或函数

logic AND function 逻辑与电路

logic NOT function 逻辑非电路

logic NOR function 逻辑或非电路

an assembled circuit 集成电路

the processing, the storage and the transmission of information 信息处理、存储和传送

assembly cost 装配成本

single chip microcomputer 单片机

process control过程控制

Microprocessor 微处理器

modular design 模块化设计

interface 接口

manual supervision 手动操作

general-purpose elements 通用元件

the large scale integrated circuit — the silicon chip

大规模集成电路-硅片

software engineering 软件工程

civilian use 民用

biometric security 生物识别安全系统

security alarm system 防盗报警系统

structured cabling 结构化布线

router 路由器

gateway 网关

ventilation 通风

air conditioning units 空调设备

illumination 照明

electron 电子

heating, ventilating, air conditioningand refrigeration 暖通空调制冷

protocol（数据传递的）协议

performance map性能图

compressor 压缩机

Micro-electromechanical Systems 微型机电系统 automated diagnostics 自动诊断

Intelligent Building智能建筑

smart home智能家居

Centralized management, decentralized control集中管理、分散控制

registers寄存器

analog circuit模拟电路

feedback 反馈

amplifier 放大器

actuator执行机构

regulate调节

Artificial intelligence人工智能

word recognition 文字识别

Adaptive Control自适应控制

telecommunication 电信

terminal 终端

water supply and discharge给排水

weak electricity弱电

architecture建筑学

manipulate 操作

office automation 办公自动化

运算放大器 operational amplifier

addition加

subtraction减

multiplication乘

integration积分

single phase circuit 单相电路

transducer 传感器HVAC&R

第三篇：自动化专业英语

1)the parameterization of the0controller0isC=X+MQ/Y-NQ。where N,M are right coprime factors of P,X,Y satisfy NX+MY=1,Q∈RH∞

2)According to the right coprime factorization of P, N=,M=,X=,Y=By the performance of the closed-loop system

N(0)[X(0)+M(0)Q(0)]=1 N(10j)[Y(10j)-N(10j)Q(10j)]=0，So take Q in the form Q(s)=x1+x2·1/s+1+x3·1/(x+

1)²

we can get the solution of Q。x1=,x2=,x3=,Q=Finally,the controller is C=

步骤:S=1-λ/λ代人 P(λ)=λ²/6λ²-5λ+1

X=-q2/r2 ,y=1+q1q2/r2 λ=1/s﹢1

N(S)=1/(s+1)²

M(s)=(s-1)(s-2)/(s+1)² X(s)=19s-11/s+1Y(s)=s+6/s+1

C=X+MQ/Y-NQ

N(0)[X(0)+M(0)Q(0)]=1 N(10j)[Y(10j)-N(10j)Q(10j)]=0

Q(0)=6，Q(10j)=-94+70j Q(s)=x1+x2·1/s+1+x3·1/(x+

1)²

x1=-79 x2=-723 x3=808 Q(s)=(-79s²-881s+6)/(s+1)²C(s)=[-60s4-598s32

2+2515s-1794s+1]/[s(s+100)(s+9)]

A control system is stable if the number of encirclements of the(-1,0)point by the GH plot is equal to the number of poles of GH with positive real parts.The direction of encirclement must be in a direction opposite to τs.GH is on open loop transfer function.τs is open right half of s-plane.一个控制系统是稳定的数量是否包围的(1,0)点的GH图的数量相等的两极与积极的真实部分GH。被包围的方向都必须在一个τs的相反方向。

“GH”是在开环传递函数上。τs在s-plane的右半平面开放。

二．The process of designing a control system generally involves many steps.A typical scenario is as follows:

1.Study the system to be controlled and decide what types of sensors and actuators will be used and where they will be placed.2.Model the resulting system to be controlled.3.Simplify the model if necessary so that it is tractable.4.Analyze the resulting model;determine its properties.5.Decide on performance specifications.6.Decide on the type of controller to be used.7.Design a controller to meet the specs, if possible;if not, modify the specs or generalize the type of controller sought.8.Simulate the resulting controlled system, either on a computer or in a pilot plant.9.Repeat from step 1 if necessary.10.Choose hardware and software and implement the controller.11.Tune the controller on-line if necessary.r．reference or command inputvsensor outputuactuating signal, plant inputdexternal disturbanceyplant output and measured signaln．sensor noise

第四篇：西工大自动化专业英语三下重点短文

1、p94The transfer function can be obtained in several ways.One method is purely mathematical and consists of taking the Laplace transform of the differential equations describing the components or system and then solving for the transfer function;nonzero initial conditions, when they occur, are treated as additional inputs.A second method is experimental.A known input(sinusoids and steps are commonly used)is apply to the system, the output is measured, and the transfer function is constructed from operating data and combination of the known transfer functions of the individual elements.This combination or reduction process is termed block diagram algebra.2、p93 In Eq.(2-1B-2)the denominator D(s)of the transfer function is called the characteristic function since it contains all the physical characteristics of the system.The characteristic equation is formed by setting D(s)equal to zero.The roots of the characteristic equation determine the stability of the system and the general nature of the transient response to any input.The numerator polynomial N(s)is a function of how the input enters the system.Consequently, N(s)does,however, along with the specific input, determine the magnitude and sign of each transient mode and thus establishes the shape of the transient response as well as the steady-state value of the output.3、p94 The Laplace transformation comes from the area of operational mathematics and is extremely useful in the analysis and design of linear systems.Ordinary differential equations with constant coefficients transform into algebraic equations that can be used to implement the transfer function concept.Furthermore, the Laplace domain is a nice place in which to work, and transfer functions may be easily manipulated, modified, and analyzed.The designer quickly becomes adept in relating changes in the Laplace domain to behavior in the time domain without actually having to solve the system equations.When time domain solutions are required, the Laplace transform method is straightforward.The solution is complete, including both the homogeneous(transient)and particular(steady-state)solutions, and initial conditions are automatically included.Finally, it is easy to move from the Laplace domain into the frequency domain.4、p96 Analytical techniques require mathematical models.The transfer function is a convenient model form for the analysis and design of stationary linear systems with a limited number of differential equations and by block diagram algebra.From the deferential or intergro-differential equations describing the behavior of a particular plant, process, or component, using the Laplace transformation and its properties can develop the transfer functions.5、p97 The stability of a continuous or discrete-time system is determined by its response to inputs or disturbance.Intuitively, a stable system is one that remains at rest(or in equilibrium)unless excited by an external source and returns to rest if all excitation are removed.The output will pass through a transient phase and settle down to a steady-state response that will be of the same form as, or bounded by, the input.If we apply the same input to an unstable system, the output will never settle down to a steady-state phase;it will increase in an unbounded manner, usually exponentially or with oscillations of increasing amplitude.6、p97 Stability can be precisely defined in terms of the impulse responsey(t)of a continuous system, or Kronecker delta responsey(k)of a discrete-time system, as follows:

A continuous(discrete-time)system is stable if its impulse responsey(t)(Kronecker delta responsey(k))approaches zero as time approaches infinity.An acceptable system must at minimum satisfy the three basic criteria of stability, accuracy, and a satisfactory transient response.These three criteria are implied in the statement that an acceptable system must have a satisfactory time response to specified inputs and disturbances.So, although we work in the Laplace and frequency domains for convenience, we must be able to relate these two domains, at least qualitatively, to the time domain.7、p99 The Routh Criterion: All the roots of the characteristic equation have real parts if and only if the elements of the first column of the Routh table have the same sign.Otherwise, the number of roots with positive real parts is equal to the number of changes of sign.The Hurwitz criterion is another method for determining whether all the roots

of the characteristic equation of a continuous system have negative real parts.It has the same principle with the Routh criterion in substantial although their forms or patterns are different, so they are commonly called Routh-Hurwitz criterion.8、The three basic performance criteria for a control system are stability, acceptable steady-state accuracy, and an acceptable transient response.With the system transfer function known, the Routh-Hurwitz criterion will tell us whether or not a system is stable.If it is stable, the steady-state accuracy can be determined for various types of inputs.To determine the nature of the transient response, we need to know the location in the s plane of the roots of the characteristic equation.Unfortunately, the characteristic equation is normally unfactored and of high order.9、The root locus technique is a graphical method of dertermining the location of the roots of the characteristic equation as any single parameter, such as a gain or time constant, is varied from zero to infinity.The root locus, therefore, provides information not only as to the absolute stability of a system but also as to its degree of stability, which is another way of describing the nature of the transient response.If the system is unstable or has an unacceptable transient response, the root locus indicates possible ways to improve the response and is a convenient method of depicting qualitatively the effects of any such changes.10、If the part of the real axis between two o.l.poles(o.l.zeros)belongs to the loci, there must be a point of breakaway from, or arrival at, the real axis.If no other poles and zeros are close by, the breakaway point will be halfway.In Fig.2-3A-2d, adding the polep3pushes the breakaway point away;a zero at the position ofp3would similarly attract the breakaway point.11、The frequency transfer function of a system or of its KZjPjfunction can be represented either by the single Nyquist diagram（a polar plot）or by plots of the amplitude ratio and the phase angle against the input（forcing）frequency.It is customary to plot the amplitude ratio in decibels and the phase angle in degrees against the common logarithm of the input frequency.In this form, the

two plots are known as Bode plots(after H.W.Bode).12、In Bode plots, the magnitude M in dB and the phase angle  in degrees are plotted against  on semilog paper.The development has shown the following：Bode magnitude and phase-angle plots of KZjPj are obtained by summing those of its elementary factors.These plot are much easier to make than polar plots or Nyquist diagrams, and can readily be interpreted in terms of different aspects of system performance.13、the plots are the mirror images of the corresponding integrator relative to the 0dB and 0axes.This is also true for the leads corresponding to the simple and quadratic lag below.The asymptotes meet at the break frequency or corner frequency given by1（or）on the normalized plot.14、Gain factor compensation: It is possible in some cases to satisfy all system specification by simple adjusting the open-loop gain factor K.Adjusting of the gain factor K does not affect the phase angle plot.It only shifts the magnitude plot up or down to correspond to the increase or decrease in K.15、Lead compensation: The addition of a cascade lead compensator to a system lowers the overall phase angle curve in the low-to-mid-frequency region.Lead compensation is normally used to increase the gain and/or phase margins of a system or increase its bandwidth.An additional modification of the Bode gain KB is usually required with lead networks.16、Lag compensation: The lag compensation is employed in some cases to decrease the bandwidth of the system, and it is also used to improve the relative stability for a given value of error constant, or to reject the noise of high-frequency.17、Lag-lead compensation: It is sometimes desirable to simultaneously employ both lead and lag compensation.Although one each of these two networks can be connected in series to achieve the desired effect, it is usually more

convenient to mechanize the combined lag-lead compensator.18、The transfer function can be obtained in several ways.One method is purely mathematical and consists of taking the Laplace transform of the differential equations describing the components or system and then solving for the transfer function;nonzero initial conditions, when they occur, are treated as additional inputs.A second method is experimental.A known input(sinusoids and steps are commonly used)is applied to the system, the output is measured, and the transfer function is constructed from operating data and curves.The transfer function for a subsystem or complete system is often obtained by proper combination of the known transfer functions of the individual elements.This combination or reduction process is termed block diagram algebra.19、Design of a feedback control system using Bode techniques entails shaping and reshaping the Bode magnitude and phase angle plots until the system specifications are satisfied.These specifications are most convenient expressed in terms of frequency-domain figures of merit such as gain and phase margin for the transient performance and the error constants for the steady-state time-domain response.And shaping the asymptotic Bode plots of continuous-time systems by cascade or feedback compensation is a relatively simple procedure.

第五篇：自动化专业英语中英对照

自动化专业英语中英文对照 retarding torque 制动转矩

inductive component 感性（无功）分量 abscissa axis 横坐标

induction generator 感应发电机

synchronous generator 同步发电机automatic station 无人值守电站hydropower station 水电站

process of self – excitation 自励过程auxiliary motor 辅助电动机

technical specifications 技术条件voltage across the terminals 端电压steady – state condition 瞬态 暂态reactive in respect to 相对….呈感性active in respect to 相对….呈阻性synchronous condenser 同步进相（调相）机

coincide in phase with 与….同相synchronous reactance 同步电抗algebraic 代数的algorithmic 算法的biphase 双相的bilateral circuit 双向电路bimotored 双马达的corridor 通路

shunt displacement current 旁路位移电流

leakage 泄漏

lightning shielding 避雷harmonic 谐波的insulator string 绝缘子串neutral 中性的zero sequence current 零序电流sinusoidal 正弦的square平方

corona 电晕,放电bypass 旁路

voltmeter 电压表ammeter 电流表micrometer 千分尺thermometer 温度计watt-hour meter 电度表wattmeter 电力表private line 专用线路diameter 直径centimeter 厘米

restriking 电弧再触发magnitude 振幅oscillation 振荡auxiliary 辅助的protective gap 保护性间隙放电receptacle 插座

lightning arrester 避雷装置bushing 套管trigger 起动装置stress 应力

deterioration 损坏,磨损spark gap 火花放电隙traveling-wave 行波

wye-connected 星形连接enclosure 设备外壳live conductor 带电导体fuse 熔断器

structural 结构上的out-of-step 不同步的resynchronize 再同步synchroscops 同步指示器

automatic oscillograph 自动示波器nominally 标称sampling 采样

potential transformer 电压互感器fraction 分数

switchyard 户外配电装置hazard 危险bushing 高压套contact 触点

energize 励磁trip coil 跳闸线圈

over-current relay 过电流继电器armature 衔铁

pickup current 始动电流release current 释放电流solenoid relay 螺管式继电器

induction-disc relay 感应圆盘式继电器cast-aluminum rotor 铸铝转子bronze 青铜horsepower 马力random-wound 散绕insulation 绝缘

ac motor 交流环电动机end ring 端环alloy 合金

inverse time relay 反时限继电器hydraulic 液力的dashpot 阻尼器pneumatic 气动的permanent magnet 永磁体electrical stressing 电气应力mechanical stressing 机械应力deviation 偏差

third harmonic voltage 三次谐波电压induction machine 感应式电机horseshoe magnet 马蹄形磁铁magnetic field 磁场eddy current 涡流

right-hand rule 右手定则left-hand rule 左手定则slip 转差率

induction motor 感应电动机rotating magnetic field 旋转磁场winding 绕组stator 定子rotor 转子

induced current 感生电流time-phase 时间相位

exciting voltage 励磁电压solt 槽

lamination 叠片

laminated core 叠片铁芯short-circuiting ring 短路环squirrel cage 鼠笼rotor core 转子铁芯coil winding 线圈绕组form-wound 模绕

performance characteristic 工作特性frequency 频率

revolutions per minute 转/分motoring 电动机驱动generating 发电

per-unit value 标么值

breakdown torque 极限转矩breakaway force 起步阻力overhauling 检修

wind-driven generator 风动发电机revolutions per second 转/秒number of poles 极数

speed-torque curve 转速力矩特性曲线plugging 反向制动

synchronous speed 同步转速percentage 百分数

locked-rotor torque 锁定转子转矩full-load torque 满载转矩prime mover 原动机

inrush current 涌流magnetizing reacance 磁化电抗

line-to-neutral 线与中性点间的staor winding 定子绕组leakage reactance 漏磁电抗no-load 空载full load 满载

Polyphase 多相(的)iron-loss 铁损

complex impedance 复数阻抗rotor resistance 转子电阻leakage flux 漏磁通locked-rotor 锁定转子chopper circuit 斩波电路separately excited 他励的compounded 复励dc motor 直流电动机de machine 直流电机speed regulation 速度调节shunt 并励series 串励

armature circuit 电枢电路optical fiber 光纤interoffice 局间的waveguide 波导 波导管bandwidth 带宽

light emitting diode 发光二极管silica 硅石 二氧化硅

regeneration 再生, 后反馈放大coaxial 共轴的,同轴的high-performance 高性能的carrier 载波mature 成熟的Single Side Band(SSB)单边带coupling capacitor 结合电容propagate 传导 传播modulator 调制器demodulator 解调器line trap 限波器shunt 分路器

Amplitude Modulation(AM 调幅

Frequency Shift Keying(FSK)移频键控

tuner 调谐器attenuate 衰减incident 入射的two-way configuration 二线制generator voltage 发电机电压dc generator 直流发电机

polyphase rectifier 多相整流器boost 增压

time constant 时间常数

forward transfer function 正向传递函数

error signal 误差信号regulator 调节器

stabilizing transformer 稳定变压器time delay 延时

direct axis transient time constant 直轴瞬变时间常数

transient response 瞬态响应solid state 固体buck 补偿

operational calculus 算符演算gain 增益pole 极点

feedback signal 反馈信号dynamic response 动态响应

voltage control system 电压控制系统mismatch 失配

error detector 误差检测器excitation system 励磁系统field current 励磁电流transistor 晶体管high-gain 高增益boost-buck 升压去磁

feedback system 反馈系统reactive power 无功功率feedback loop 反馈回路

automatic Voltage regulator(AVR)自动电压调整器

reference Voltage 基准电压magnetic amplifier 磁放大器amplidyne 微场扩流发电机self-exciting 自励的limiter 限幅器

manual control 手动控制block diagram 方框图linear zone 线性区

potential transformer 电压互感器stabilization network 稳定网络stabilizer 稳定器

air-gap flux 气隙磁通saturation effect 饱和效应saturation curve 饱和曲线flux linkage 磁链per unit value 标么值shunt field 并励磁场magnetic circuit 磁路

load-saturation curve 负载饱和曲线air-gap line 气隙磁化线

polyphase rectifier 多相整流器circuit components 电路元件

circuit parameters 电路参数electrical device 电气设备electric energy 电能primary cell 原生电池

energy converter 电能转换器conductor 导体

heating appliance 电热器direct-current 直流

time invariant 时不变的self-inductor 自感mutual-inductor 互感the dielectric 电介质storage battery 蓄电池

e.m.f = electromotive fore 电动势unidirectional current 单方向性电流circuit diagram 电路图

load characteristic 负载特性terminal voltage 端电压

external characteristic 外特性conductance 电导volt-ampere characteristics 伏安特性carbon-filament lamp 碳丝灯泡ideal source 理想电源internal resistance 内阻

active(passive)circuit elements 有（无）源电路元件

leakage current 漏电流circuit branch 支路

P.D.= potential drop 电压降potential distribution 电位分布

r.m.s values = root mean square values 均方根值

effective values 有效值

steady direct current 恒稳直流电

sinusoidal time function 正弦时间函数complex number 复数

Cartesian coordinates 笛卡儿坐标系modulus 模real part 实部

imaginary part 虚部

displacement current 位移电流

trigonometric transformations 瞬时值epoch angle 初相角

phase displacement 相位差signal amplifier 小信号放大器mid-frequency band 中频带

bipolar junction transistor(BJT)双极性晶体管

field effect transistor(FET)场效应管electrode 电极 电焊条polarity 极性gain 增益

isolation 隔离 分离 绝缘 隔振emitter 发射管 放射器 发射极collector 集电极base 基极

self-bias resistor 自偏置电阻triangular symbol 三角符号

phase reversal 反相

infinite voltage gain 无穷大电压增益feedback component 反馈元件differentiation 微分integration 积分下限impedance 阻抗fidelity 保真度

summing circuit 总和线路 反馈系统中的比较环节

Oscillation 振荡inverse 倒数admittance 导纳transformer 变压器turns ratio 变比 匝比ampere-turns 安匝(数)mutual flux 交互(主)磁通vector equation 向(相)量方程power frequency 工频

capacitance effect 电容效应induction machine 感应电机shunt excited 并励series excited 串励separately excited 他励self excited 自励

field winding 磁场绕组 励磁绕组speed-torque characteristic 速度转矩特性

dynamic-state operation 动态运行salient poles 凸极excited by 励磁field coils 励磁线圈

air-gap flux distribution 气隙磁通分布direct axis 直轴

armature coil 电枢线圈

rotating commutator 旋转（整流子）换向器

commutator-brush combination 换向器-电刷总线

mechanical rectifier 机械式整流器armature m.m.f.wave 电枢磁势波Geometrical position 几何位置magnetic torque 电磁转矩spatial waveform 空间波形

sinusoidal – density wave 正弦磁密度

external armature circuit 电枢外电路instantaneous electric power 瞬时电功率

instantaneous mechanical power 瞬时机械功率

effects of saturation 饱和效应reluctance 磁阻

power amplifier 功率放大器compound generator 复励发电机rheostat 变阻器

self – excitation process 自励过程commutation condition 换向状况

cumulatively compounded motor 积复励电动机

operating condition 运行状态

equivalent T – circuit T型等值电路rotor(stator)winding 转子（定子绕组）winding loss 绕组（铜）损耗prime motor 原动机

active component 有功分量reactive component 无功分量electromagnetic torque 电磁转矩