智能避障机器人设计外文翻译
机器人机构设计中英文对照外文翻译文献
Abstract
In optimal design for robot structures, design modelsneed to he modified and computed repeatedly. Becausemodifying usually can not automaticallyberun, itconsumes a lot of time.Thispaper gives a method thatuses APDL language of ANSYS5.5software togenerate an optimal control program, which mikeoptimal procedure run automatically and optimalefficiency be improved.
A lot of methods are used in optimization design ofstructure. Finite element method is a much effectivemethod. In general, modeling and modifying are manual,whichisfeasible when model is simple. When modeliscomplicated, optimization timeislonger. In the longeroptimization time, calculation time is usually very little,a majorityoftime is used for modeling and modifying.It is key of improving efficiency of structureoptimization how to reduce modeling and modifyingtime.
工业机器人中英文翻译、外文文献翻译、外文翻译
工业机器人中英文翻译、外文文献翻译、外文翻译外文原文:RobotAfter more than 40 years of development, since its first appearance till now, the robot has already been widely applied in every industrial fields, and it has become the important standard of industry modernization.Robotics is the comprehensive technologies that combine with mechanics, electronics, informatics and automatic control theory. The level of the robotic technology has already been regarded as the standard of weighing a national modern electronic-mechanical manufacturing technology.Over the past two decades, the robot has been introduced into industry to perform many monotonous and often unsafe operations. Because robots can perform certain basic more quickly and accurately than humans, they are being increasingly used in various manufacturing industries.With the maturation and broad application of net technology, the remote control technology of robot based on net becomes more and more popular in modern society. It employs the net resources in modern society which are already three to implement the operatio of robot over distance. It also creates many of new fields, such as remote experiment, remote surgery, and remote amusement. What's more, in industry, it can have a beneficial impact upon the conversion of manufacturing means.The key words are reprogrammable and multipurpose because most single-purpose machines do not meet these two requirements. The term “reprogrammable” implies two things: The robot operates according to a written program, and this program can be rewritten to accommodate a variety of manufacturing tasks. The term “multipurpose” means that the robot can perform many different functions, depending on the program and tooling currently in use.Developed from actuating mechanism, industrial robot can imitation some actions and functions of human being, which can be used to moving all kinds of material components tools and so on, executing mission by execuatable program multifunctionmanipulator. It is extensive used in industry and agriculture production, astronavigation and military engineering.During the practical application of the industrial robot, the working efficiency and quality are important index of weighing the performance of the robot. It becomes key problems which need solving badly to raise the working efficiencies and reduce errors of industrial robot in operating actually. Time-optimal trajectory planning of robot is that optimize the path of robot according to performance guideline of minimum time of robot under all kinds of physical constraints, which can make the motion time of robot hand minimum between two points or along the special path. The purpose and practical meaning of this research lie enhance the work efficiency of robot.Due to its important role in theory and application, the motion planning of industrial robot has been given enough attention by researchers in the world. Many researchers have been investigated on the path planning for various objectives such as minimum time, minimum energy, and obstacle avoidance.The basic terminology of robotic systems is introduced in the following:A robot is a reprogrammable, multifunctional manipulator designed to move parts, materials, tools, or special devices through variable programmed motions for the performance of a variety of different task. This basic definition leads to other definitions, presented in the following paragraphs that give a complete picture of a robotic system.Preprogrammed locations are paths that the robot must follow to accomplish work. At some of these locations, the robot will stop and perform some operation, such as assembly of parts, spray painting, or welding. These preprogrammed locations are stored in the robot’s memory and are recalled later for continuous operation. Furthermore, these preprogrammed locations, as well as other programming feature, an industrial robot is very much like a computer, where data can be stored and later recalled and edited.The manipulator is the arm of the robot. It allows the robot to bend, reach, and twist. This movement is provided by the manipulator’s axes, also called the degrees of freedom of the robot. A robot can have from 3 to 16 axes. The term degrees of freedom will always relate to the number of axes found on a robot.The tooling and grippers are not part of the robotic system itself: rather, they areattachments that fit on the end of the robot’s arm. These attachments connected to the end of the robot’s arm allow the robot to lift parts, spot-weld, paint, arc-well, drill, deburr, and do a variety of tasks, depending on what is required of the robot.The robotic system can also control the work cell of the operating robot. The work cell of the robot is the total environment in which the robot must perform its task. Included within this cell may be the controller, the robot manipulator, a work table, safety features, or a conveyor. All the equipment that is required in order for the robot to do its job is included in the work cell. In addition, signals from outside devices can communicate with the robot in order to tell the robot when it should assemble parts, pick up parts, or unload parts to a conveyor.The robotic system has three basic components: the manipulator, the controller, and the power source.ManipulatorThe manipulator, which dose the physical work of the robotic system, consists of two sections: the mechanical section and the attached appendage. The manipulator also has a base to which the appendages are attached.The base of the manipulator is usually fixed to the floor of the work area. Sometimes, though, the base may be movable. In this case, the base is attached to either a rail or a track, allowing the manipulator to be moved from one location to anther.As mentioned previously, the appendage extends from the base of the robot. The appendage is the arm of the robot. It can be either a straight, movable arm or a jointed arm. The jointed arm is also known as an articulated arm.The appendages of the robot manipulator give the manipulator its various axes of motion. These axes are attached to a fixed base, which, in turn, is secured to a mounting. This mounting ensures that the manipulator will remain in one location.At the end of the arm, a wrist is connected. The wrist is made up of additional axes and a wrist flange. The wrist flange allows the robot user to connect different tooling to the wrist for different jobs.The manipulator’s axes allow it to perform work within a certain area. This area is called the work cell of the robot, and its size corresponds to the size of the manipulator. As the robot’s physical size increases, the size of the work cell must also increase.The movement of the manipulator is controlled by actuators, or drive system. The actuator, or drive system, allows the various axes to move within the work cell. The drive system can use electric, hydraulic, or pneumatic power. The energy developed by the drive system is converted to mechanical power by various mechanical drive systems. The drive systems are coupled through mechanical linkages. These linkages, in turn, drive the different axes of the robot. The mechanical linkages may be composed of chains, gears, and ball screws.ControllerThe controller in the robotic system is the heart of the operation. The controller stores preprogrammed information for later recall, controls peripheral devices, and communicates with computers within the plant for constant updates in production.The controller is used to control the robot manipulator’s movements as well as to control peripheral components within the work cell. The user can program the movements of the manipulator into the controller through the use of a hand-held teach pendant. This information is stored in the memory of the controller for later recall. The controller stores all program data for the robotic system. It can store several different programs, and any of these programs can be edited.The controller is also required to communicate with peripheral equipment within the work cell. For example, the controller has an input line that identifies when a machining operation is completed. When the machine cycle is completed, the input line turns on, telling the controller to position the manipulator so that it can pick up the finished part. Then, a new part is picked up by the manipulator and placed into the machine. Next, the controller signals the machine to start operation.The controller can be made from mechanically operated drums that step through a sequence of events. This type of controller operates with a very simple robotic system. The controllers found on the majority of robotic systems are more complex devices and represent state-of-the-art electronics. This is, they are microprocessor-operated. These microprocessors are either 8-bit, 16-bit, or 32-bit processors. This power allows the controller to the very flexible in its operation.The controller can send electric signals over communication lines that allow it to talk with the various axes of the manipulator. This two-way communication between therobot manipulator and the controller maintains a constant update of the location and the operation of the system. The controller also controls any tooling placed on the end of the robot’s wrist.The controller also has the job of communicating with the different plant computers. The communication link establishes the robot as part of a computer-assisted manufacturing (CAM) system.As the basic definition stated, the robot is a reprogrammable, multifunctional manipulator. Therefore, the controller must contain some type of memory storage. The microprocessor-based systems operate in conjunction with solid-state memory devices. These memory devices may be magnetic bubbles, random-access memory, floppy disks, or magnetic tape. Each memory storage device stores program information for later recall or for editing.Power supplyThe power supply is the unit that supplies power to the controller and the manipulator. Two types of power are delivered to the robotic system. One type of power is the AC power for operation of the controller. The other type of power is used for driving the various axes of the manipulator. For example, if the robot manipulator is controlled by hydraulic or pneumatic drives, control signals are sent to these devices, causing motion of the robot.For each robotic system, power is required to operate the manipulator. This power can be developed from either a hydraulic power source, a pneumatic power source, or an electric power source. These power sources are part of the total components of the robotic work cell.Classification of RobotsIndustrial robots vary widely in size, shape, number of axes, degrees of freedom, and design configuration. Each factor influences the dimensions of the robot’s working envelope or the volume of space within which it can move and perform its designated task. A broader classification of robots can been described as blew.Fixed and Variable-Sequence Robots. The fixed-sequence robot (also called a pick-and place robot) is programmed for a specific sequence of operations. Its movements are from point to point, and the cycle is repeated continuously. Thevariable-sequence robot can be programmed for a specific sequence of operations but can be reprogrammed to perform another sequence of operation.Playback Robot. An operator leads or walks the playback robot and its end effector through the desired path. The robot memorizes and records the path and sequence of motions and can repeat them continually without any further action or guidance by the operator.Numerically Controlled Robot. The numerically controlled robot is programmed and operated much like a numerically controlled machine. The robot is servo-controlled by digital data, and its sequence of movements can be changed with relative ease.Intelligent Robot. The intellingent robot is capable of performing some of the functions and tasks carried out by human beings. It is equipped with a variety of sensors with visual and tactile capabilities.Robot ApplicationsThe robot is a very special type of production tool; as a result, the applications in which robots are used are quite broad. These applications can be grouped into three categories: material processing, material handling and assembly.In material processing, robots use to process the raw material. For example, the robot tools could include a drill and the robot would be able to perform drilling operations on raw material.Material handling consists of the loading, unloading, and transferring of workpieces in manufacturing facilities. These operations can be performed reliably and repeatedly with robots, thereby improving quality and reducing scrap losses.Assembly is another large application area for using robotics. An automatic assembly system can incorporate automatic testing, robot automation and mechanical handling for reducing labor costs, increasing output and eliminating manual handling concerns.Hydraulic SystemThere are only three basic methods of transmitting power: electrical, mechanical, and fluid power. Most applications actually use a combination of the three methods to obtain the most efficient overall system. To properly determine which principle method to use, it is important to know the salient features of each type. For example, fluidsystems can transmit power more economically over greater distances than can mechanical type. However, fluid systems are restricted to shorter distances than are electrical systems.Hydraulic power transmission systems are concerned with the generation, modulation, and control of pressure and flow, and in general such systems include:1.Pumps which convert available power from the prime mover to hydraulicpower at the actuator.2.Valves which control the direction of pump-flow, the level of powerproduced, and the amount of fluid-flow to the actuators. The power level isdetermined by controlling both the flow and pressure level.3.Actuators which convert hydraulic power to usable mechanical power outputat the point required.4.The medium, which is a liquid, provides rigid transmission and control aswell as lubrication of components, sealing in valves, and cooling of thesystem.5.Connectors which link the various system components, provide powerconductors for the fluid under pressure, and fluid flow return totank(reservoir).6.Fluid storage and conditioning equipment which ensure sufficient quality andquantity as well as cooling of the fluid..Hydraulic systems are used in industrial applications such as stamping presses, steel mills, and general manufacturing, agricultural machines, mining industry, aviation, space technology, deep-sea exploration, transportation, marine technology, and offshore gas and petroleum exploration. In short, very few people get through a day of their lives without somehow benefiting from the technology of hydraulics.The secret of hydraulic system’s success and widespread use is its versatility and manageability. Fluid power is not hindered by the geometry of the machine as is the case in mechanical systems. Also, power can be transmitted in almost limitless quantities because fluid systems are not so limited by the physical limitations of materials as are the electrical systems. For example, the performance of an electromagnet is limited by the saturation limit of steel. On the other hand, the powerlimit of fluid systems is limited only by the strength capacity of the material.Industry is going to depend more and more on automation in order to increase productivity. This includes remote and direct control of production operations, manufacturing processes, and materials handling. Fluid power is the muscle of automation because of advantages in the following four major categories.1.Ease and accuracy of control. By the use of simple levers and push buttons,the operator of a fluid power system can readily start, stop, speed up or slowdown, and position forces which provide any desired horsepower withtolerances as precise as one ten-thousandth of an inch. Fig. shows a fluidpower system which allows an aircraft pilot to raise and lower his landinggear. When the pilot moves a small control valve in one direction, oil underpressure flows to one end of the cylinder to lower the landing gear. To retractthe landing gear, the pilot moves the valve lever in the opposite direction,allowing oil to flow into the other end of the cylinder.2.Multiplication of force. A fluid power system (without using cumbersomegears, pulleys, and levers) can multiply forces simply and efficiently from afraction of an ounce to several hundred tons of output.3.Constant force or torque. Only fluid power systems are capable of providingconstant force or torque regardless of speed changes. This is accomplishedwhether the work output moves a few inches per hour, several hundred inchesper minute, a few revolutions per hour, or thousands of revolutions perminute.4.Simplicity, safety, economy. In general, fluid power systems use fewermoving parts than comparable mechanical or electrical systems. Thus, theyare simpler to maintain and operate. This, in turn, maximizes safety,compactness, and reliability. For example, a new power steering controldesigned has made all other kinds of power systems obsolete on manyoff-highway vehicles. The steering unit consists of a manually operateddirectional control valve and meter in a single body. Because the steering unitis fully fluid-linked, mechanical linkages, universal joints, bearings, reductiongears, etc. are eliminated. This provides a simple, compact system. Inapplications. This is important where limitations of control space require asmall steering wheel and it becomes necessary to reduce operator fatigue.Additional benefits of fluid power systems include instantly reversible motion, automatic protection against overloads, and infinitely variable speed control. Fluid power systems also have the highest horsepower per weight ratio of any known power source. In spite of all these highly desirable features of fluid power, it is not a panacea for all power transmission problems. Hydraulic systems also have some drawbacks. Hydraulic oils are messy, and leakage is impossible to completely eliminate. Also, most hydraulic oils can cause fires if an oil leak occurs in an area of hot equipment.Pneumatic SystemPneumatic system use pressurized gases to transmit and control power. As the name implies, pneumatic systems typically use air (rather than some other gas ) as the fluid medium because air is a safe, low-cost, and readily available fluid. It is particularly safe in environments where an electrical spark could ignite leaks from system components.In pneumatic systems, compressors are used to compress and supply the necessary quantities of air. Compressors are typically of the piston, vane or screw type. Basically a compressor increases the pressure of a gas by reducing its volume as described by the perfect gas laws. Pneumatic systems normally use a large centralized air compressor which is considered to be an infinite air source similar to an electrical system where you merely plug into an electrical outlet for electricity. In this way, pressurized air can be piped from one source to various locations throughout an entire industrial plant. The compressed air is piped to each circuit through an air filter to remove contaminants which might harm the closely fitting parts of pneumatic components such as valve and cylinders. The air then flows through a pressure regulator which reduces the pressure to the desired level for the particular circuit application. Because air is not a good lubricant (contains about 20% oxygen), pneumatics systems required a lubricator to inject a very fine mist of oil into the air discharging from the pressure regulator. This prevents wear of the closely fitting moving parts of pneumatic components.Free air from the atmosphere contains varying amounts of moisture. This moisture can be harmful in that it can wash away lubricants and thus cause excessive wear andcorrosion. Hence, in some applications, air driers are needed to remove this undesirable moisture. Since pneumatic systems exhaust directly into the atmosphere , they are capable of generating excessive noise. Therefore, mufflers are mounted on exhaust ports of air valves and actuators to reduce noise and prevent operating personnel from possible injury resulting not only from exposure to noise but also from high-speed airborne particles.There are several reasons for considering the use of pneumatic systems instead of hydraulic systems. Liquids exhibit greater inertia than do gases. Therefore, in hydraulic systems the weight of oil is a potential problem when accelerating and decelerating and decelerating actuators and when suddenly opening and closing valves. Due to Newton’s law of motion ( force equals mass multiplied by acceleration ), the force required to accelerate oil is many times greater than that required to accelerate an equal volume of air. Liquids also exhibit greater viscosity than do gases. This results in larger frictional pressure and power losses. Also, since hydraulic systems use a fluid foreign to the atmosphere , they require special reservoirs and no-leak system designs. Pneumatic systems use air which is exhausted directly back into the surrounding environment. Generally speaking, pneumatic systems are less expensive than hydraulic systems.However, because of the compressibility of air, it is impossible to obtain precise controlled actuator velocities with pneumatic systems. Also, precise positioning control is not obtainable. While pneumatic pressures are quite low due to compressor design limitations ( less than 250 psi ), hydraulic pressures can be as high as 10,000 psi. Thus, hydraulics can be high-power systems, whereas pneumatics are confined to low-power applications. Industrial applications of pneumatic systems are growing at a rapid pace. Typical examples include stamping, drilling, hoist, punching, clamping, assembling, riveting, materials handling, and logic controlling operations.工业机器人机器人自问世以来到现在,经过了40多年的发展,已被广泛应用于各个工业领域,已成为工业现代化的重要标志。
智能机器人的介绍作文英语
智能机器人的介绍作文英语In the realm of modern technology, the concept of smart robots has become increasingly prevalent, transforming various sectors from manufacturing to healthcare. Smart robots are sophisticated machines designed to perform tasks autonomously or with minimal human intervention. They are equipped with advanced sensors, powerful processors, and artificial intelligence (AI) algorithms that enable them to perceive their environment, make decisions, and learn from experience.The development of smart robots is a testament to the rapid evolution of AI and machine learning. These robots are not just programmable to execute specific tasks; they are capable of adapting to new situations and improving their performance over time. Here's a deeper look into the world of smart robots:1. Capabilities: Smart robots can be found in various forms, from humanoid machines that can interact with humans to industrial robots that can assemble complex products with precision. They are capable of tasks such as object recognition, navigation, and manipulation.2. Applications: The applications of smart robots are vast. In the industrial sector, they are used for automation, increasing efficiency and reducing the potential for human error. In healthcare, they assist in surgeries and patientcare. In the service industry, they serve as receptionists, waiters, and even personal assistants.3. AI Integration: The integration of AI in smart robots allows them to process complex data and make informed decisions. They can learn from their mistakes and optimize their performance based on the feedback they receive.4. Sensory Perception: Equipped with an array of sensors, smart robots can perceive their surroundings in ways similar to humans. They can see with cameras, hear with microphones, and feel with touch sensors.5. Mobility: Many smart robots are designed with mobility in mind. They can move on wheels, walk on legs, or even fly with the help of drones, allowing them to navigate diverse terrains.6. Ethical Considerations: As with any technology, the rise of smart robots brings ethical questions. Issues such as job displacement, privacy concerns, and the potential for misuse are important to address as this technology advances.7. Future Prospects: The future of smart robots is promising. As technology continues to advance, we can expect to see more sophisticated, versatile, and intelligent robots that will become an integral part of our daily lives.In conclusion, smart robots represent the cutting edge of technology, offering a glimpse into a future where machines and humans coexist and collaborate in a variety of settings.As these robots become more integrated into society, it will be crucial to navigate the ethical and practical challenges they present to ensure a harmonious and beneficial coexistence.。
智能避障机器人设计文献综述
智能避障机器人设计文献综述1 前言我们从广泛意义上理解所谓的智能机器人,它给人的最深刻的印象是一个独特的进行自我控制的“活物”。
其实,这个自控“活物”的主要器官并没有像真正的人那样微妙而复杂。
智能机器人具备形形色色的内部信息传感器和外部信息传感器,如视觉、听觉、触觉、嗅觉。
除具有感受器外,它还有效应器,作为作用于周围环境的手段。
这就是筋肉,或称自整步电动机,它们使手、脚、长鼻子、触角等动起来。
机器人技术自上个世纪中叶问世以来,经历四十多年发展已取得长足进步,成为提高产业竞争力方面极为重要的战略高技术。
目前,机器人关键技术日臻成熟,应用范围迅速扩展,作为计算机、自动控制、传感器、先进制造等领域技术集成的典型代表,面临巨大产业发展机会。
国内外业界专家预测,智能机器人将是21世纪高技术产业新的增长方向。
2003至2006年间,全球智能服务机器人以每年40%左右的速度迅速增长。
当代机器人专家现已达成了共识:作为计算机技术及现代IT综合技术的一个必然延伸,机器人技术完全可能遵循“摩尔定律”,以前所未有的速度实现突破。
智能机器人将成为继家电、个人电脑之后、第三个以超常规速度走向我们日常生活的产品。
如今知识工程、计算机科学、机电一体化和工业一体化等许多领域都在讨论智能系统,人们要求系统变得越来越智能化。
显然传统的控制观念是无法满足人们的需求,而智能控制与这些传统的控制有机的结合起来取长补短,提高整体的优势更好的满足人们的需求。
随着人工智能技术、计算机技术、自动控制技术的迅速发展,智能控制必将迎来它的发展新时代。
计算机控制与电子技术的融合为电子设备智能化开辟了广阔前景。
因此,智能技术的研究、应用都是非常有意义而且有很高市场价值的[1]。
智能机器人,也称轮式智能小车,是一种以汽车电子为背景,涵盖控制、模式识别、传感技术、电子、电气、计算机、机械等多科学的科技创意性设计,一般主要由单片机模块、驱动模块、红外传感器模块和电源模块等模块组成。
机器人外文文献翻译、中英文翻译
外文资料robotThe industrial robot is a tool that is used in the manufacturing environment to increase productivity. It can be used to do routine and tedious assembly line jobs,or it can perform jobs that might be hazardous to the human worker . For example ,one of the first industrial robot was used to replace the nuclear fuel rods in nuclear power plants. A human doing this job might be exposed to harmful amounts of radiation. The industrial robot can also operate on the assembly line,putting together small components,such as placing electronic components on a printed circuit board. Thus,the human worker can be relieved of the routine operation of this tedious task. Robots can also be programmed to defuse bombs,to serve the handicapped,and to perform functions in numerous applications in our society.The robot can be thought of as a machine that will move an end-of-tool ,sensor ,and/or gripper to a preprogrammed location. When the robot arrives at this location,it will perform some sort of task .This task could be welding,sealing,machine loading ,machine unloading,or a host of assembly jobs. Generally,this work can be accomplished without the involvement of a human being,except for programming and for turning the system on and off.The basic terminology of robotic systems is introduced in the following:1. A robot is a reprogrammable ,multifunctional manipulator designed to move parts,material,tool,or special devices through variable programmed motions for the performance of a variety of different task. This basic definition leads to other definitions,presented in the following paragraphs,that give acomplete picture of a robotic system.2. Preprogrammed locations are paths that the robot must follow to accomplish work,At some of these locations,the robot will stop and perform some operation ,such as assembly of parts,spray painting ,or welding .These preprogrammed locations are stored in the robot’s memory and are recalled later for continuousoperation.Furthermore,these preprogrammed locations,as well as other program data,can be changed later as the work requirements change.Thus,with regard to this programming feature,an industrial robot is very much like a computer ,where data can be stoned and later recalled and edited.3. The manipulator is the arm of the robot .It allows the robot to bend,reach,and twist.This movement is provided by the manipulator’s axes,also called the degrees of freedom of the robot .A robot can have from 3 to 16 axes.The term degrees of freedom will always relate to the number of axes found on a robot.4. The tooling and frippers are not part the robotic system itself;rather,they are attachments that fit on the end of the robot’s arm. These attachments connected to the end of the robot’s arm allow the robot to lift parts,spot-weld ,paint,arc-weld,drill,deburr,and do a variety of tasks,depending on what is required of the robot.5. The robotic system can control the work cell of the operating robot.The work cell of the robot is the total environment in which the robot must perform itstask.Included within this cell may be the controller ,the robot manipulator ,a work table ,safety features,or a conveyor.All the equipment that is required in order for the robot to do its job is included in the work cell .In addition,signals from outside devices can communicate with the robot to tell the robot when it should parts,pick up parts,or unload parts to a conveyor.The robotic system has three basic components: the manipulator,the controller,and the power source.A.ManipulatorThe manipulator ,which does the physical work of the robotic system,consists of two sections:the mechanical section and the attached appendage.The manipulator also has a base to which the appendages are attached.Fig.1 illustrates the connectionof the base and the appendage of a robot.图1.Basic components of a robot’s manipulatorThe base of the manipulator is usually fixed to the floor of the work area. Sometimes,though,the base may be movable. In this case,the base is attached to either a rail or a track,allowing the manipulator to be moved from one location to anther.As mentioned previously ,the appendage extends from the base of the robot. The appendage is the arm of the robot. It can be either a straight ,movable arm or a jointed arm. The jointed arm is also known as an articulated arm.The appendages of the robot manipulator give the manipulator its various axes of motion. These axes are attached to a fixed base ,which,in turn,is secured to a mounting. This mounting ensures that the manipulator will in one location.At the end of the arm ,a wrist(see Fig 2)is connected. The wrist is made up of additional axes and a wrist flange. The wrist flange allows the robot user to connect different tooling to the wrist for different jobs.图2.Elements of a work cell from the topThe manipulator’s axes allow it to perform work within a certain area. The area is called the work cell of the robot ,and its size corresponds to the size of the manipulator.(Fid2)illustrates the work cell of a typical assembly ro bot.As the robot’s physical size increases,the size of the work cell must also increase.The movement of the manipulator is controlled by actuator,or drive systems.The actuator,or drive systems,allows the various axes to move within the work cell. The drive system can use electric,hydraulic,or pneumatic power.The energy developed by the drive system is converted to mechanical power by various mechanical power systems.The drive systems are coupled through mechanical linkages.These linkages,in turn,drive the different axes of the robot.The mechanical linkages may be composed of chain,gear,and ball screws.B.ControllerThe controller in the robotic system is the heart of the operation .The controller stores preprogrammed information for later recall,controls peripheral devices,and communicates with computers within the plant for constant updates in production.The controller is used to control the robot manipulator’s movements as well as to control peripheral components within the work cell. The user can program the movements of the manipulator into the controller through the use of a hard-held teach pendant.This information is stored in the memory of the controller for later recall.The controller stores all program data for the robotic system.It can store several differentprograms,and any of these programs can be edited.The controller is also required to communicate with peripheral equipment within the work cell. For example,the controller has an input line that identifies when a machining operation is completed.When the machine cycle is completed,the input line turn on telling the controller to position the manipulator so that it can pick up the finished part.Then ,a new part is picked up by the manipulator and placed into the machine.Next,the controller signals the machine to start operation.The controller can be made from mechanically operated drums that step through a sequence of events.This type of controller operates with a very simple robotic system.The controllers found on the majority of robotic systems are more complex devices and represent state-of-the-art eletronoics.That is,they are microprocessor-operated.these microprocessors are either 8-bit,16-bit,or 32-bit processors.this power allows the controller to be very flexible in its operation.The controller can send electric signals over communication lines that allow it to talk with the various axes of the manipulator. This two-way communication between the robot manipulator and the controller maintains a constant update of the end the operation of the system.The controller also controls any tooling placed on the end of the robot’s wrist.The controller also has the job of communicating with the different plant computers. The communication link establishes the robot as part a computer-assisted manufacturing (CAM)system.As the basic definition stated,the robot is a reprogrammable,multifunctional manipulator.Therefore,the controller must contain some of memory stage. The microprocessor-based systems operates in conjunction with solid-state devices.These memory devices may be magnetic bubbles,random-access memory,floppy disks,or magnetic tape.Each memory storage device stores program information fir or for editing.C.power supplyThe power supply is the unit that supplies power to the controller and the manipulator. The type of power are delivered to the robotic system. One type of power is the AC power for operation of the controller. The other type of power isused for driving the various axes of the manipulator. For example,if the robot manipulator is controlled by hydraulic or pneumatic drives,control signals are sent to these devices causing motion of the robot.For each robotic system,power is required to operate the manipulator .This power can be developed from either a hydraulic power source,a pneumatic power source,or an electric power source.There power sources are part of the total components of the robotic work cell.中文翻译机器人工业机器人是在生产环境中用以提高生产效率的工具,它能做常规乏味的装配线工作,或能做那些对于工人来说是危险的工作,例如,第一代工业机器人是用来在核电站中更换核燃料棒,如果人去做这项工作,将会遭受有害放射线的辐射。
智能导盲犬机器人作文儿
智能导盲犬机器人作文儿英文回答:Intelligent guide dog robots are a remarkableinnovation that has greatly improved the lives of visually impaired individuals. These robots are designed to provide assistance and support to blind people, helping them navigate their surroundings with ease and independence.With advanced sensors and artificial intelligence technology, these robots can detect obstacles, avoid collisions, and guide their users through various environments.One of the main advantages of intelligent guide dog robots is their ability to adapt to different situationsand environments. For example, if a blind person is walking on a crowded street, the robot can analyze the surroundings and find the safest path to navigate through the crowd. It can also detect and avoid obstacles such as potholes, curbs, or low-hanging branches. This level of adaptability ensuresthat visually impaired individuals can move around confidently and safely.Moreover, these robots are equipped with voice recognition and natural language processing capabilities, allowing users to communicate with them easily. For instance, a blind person can simply say, "Robot, find the nearest coffee shop," and the robot will use its GPS and mapping system to provide directions. This feature not only enhances convenience but also promotes independence for visually impaired individuals.In addition, intelligent guide dog robots offer a range of other useful features. They can assist with daily tasks such as retrieving objects, opening doors, or even helping with grocery shopping. These robots are also programmed to recognize and respond to emergency situations. For example, if a blind person falls down, the robot can immediately alert nearby individuals or emergency services for assistance.中文回答:智能导盲犬机器人是一项令人瞩目的创新,极大地改善了视力受损人士的生活。
机器人外文翻译(中英文翻译)
机器人外文翻译(中英文翻译)机器人外文翻译(中英文翻译)With the rapid development of technology, the use of robots has become increasingly prevalent in various industries. Robots are now commonly employed to perform tasks that are dangerous, repetitive, or require a high level of precision. However, in order for robots to effectively communicate with humans and fulfill their intended functions, accurate translation between different languages is crucial. In this article, we will explore the importance of machine translation in enabling robots to perform translation tasks, as well as discuss current advancements and challenges in this field.1. IntroductionMachine translation refers to the use of computer algorithms to automatically translate text or speech from one language to another. The ultimate goal of machine translation is to produce translations that are as accurate and natural as those generated by human translators. In the context of robots, machine translation plays a vital role in allowing them to understand and respond to human commands, as well as facilitating communication between robots of different origins.2. Advancements in Machine TranslationThe field of machine translation has experienced significant advancements in recent years, thanks to breakthroughs in artificial intelligence and deep learning. These advancements have led to the development of neural machine translation (NMT) systems, which have greatly improved translation quality. NMT models operate by analyzinglarge amounts of bilingual data, allowing them to learn the syntactic and semantic structures of different languages. As a result, NMT systems are capable of providing more accurate translations compared to traditional rule-based or statistical machine translation approaches.3. Challenges in Machine Translation for RobotsAlthough the advancements in machine translation have greatly improved translation quality, there are still challenges that need to be addressed when applying machine translation to robots. One prominent challenge is the variability of language use, including slang, idioms, and cultural references. These nuances can pose difficulties for machine translation systems, as they often require a deep understanding of the context and cultural background. Researchers are currently working on developing techniques to enhance the ability of machine translation systems to handle such linguistic variations.Another challenge is the real-time requirement of translation in a robotic setting. Robots often need to process and translate information on the fly, and any delay in translation can affect the overall performance and efficiency of the robot. Optimizing translation speed without sacrificing translation quality is an ongoing challenge for researchers in the field.4. Applications of Robot TranslationThe ability for robots to translate languages opens up a wide range of applications in various industries. One application is in the field of customer service, where robots can assist customers in multiple languages, providing support and information. Another application is in healthcare settings, where robots can act as interpreters between healthcare professionals and patientswho may speak different languages. Moreover, in international business and diplomacy, robots equipped with translation capabilities can bridge language barriers and facilitate effective communication between parties.5. ConclusionIn conclusion, machine translation plays a crucial role in enabling robots to effectively communicate with humans and fulfill their intended functions. The advancements in neural machine translation have greatly improved translation quality, but challenges such as language variability and real-time translation requirements still exist. With continuous research and innovation, the future of machine translation for robots holds great potential in various industries, revolutionizing the way we communicate and interact with technology.。
机器人机构设计中英文对照外文翻译文献
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FEM Optimization for Robot Structure
Wang Shijun, Zhao Jinjuan*
Department of Mechanical Engineering, Xi'anUniversity of Technology
Shaanxi Province, People's Republic of Chinarobot is a kind of machine, which is controlledby computers. Because efficiency and maneuverabilityare higher than traditional machines, industrial robot isused extensively in industry. For thesakeof efficiencyand maneuverability, reducing mass and increasingstiffness is more important than traditional machines,instructure design of industrial robot.
Fig. 1 shows the main framework of a parallel robot withthree bars. When the length of three bars are changed,conjunct end of three bars can follow a given track,where robot handisinstalled. Coreof top beamistriangle, owing to three bars used inthedesign,whichisshowed in Fig.2. Use of three bars makes top beamnonsymmetrical along the plane that is defined by twocolumns. According to a qualitative analysis from Fig.1,Stiffness values along z-axis are different at three jointlocations on the top beam and stiffness at the locationbetween bar 1 and top beam is lowest, which isconfirmed by computing results of finite element, too.According to design goal, stiffness difference at threejoint locations must he within a given tolerance.Inconsistent of stiffness will have influence on themotion accuracy of the manipulator under high load,soit is necessary to find the accurate location of top beamalong x-axis.
智能机器人英文文档
Obstacle Avoidance Design for Humanoid RobotBased on Four Infrared SensorsChing-Chang Wong1*, Chi-Tai Cheng1, Kai-Hsiang Huang1, Yu-Ting Yang1,Hsiang-Min Chan1 and Chii-Sheng Yin21Department of Electrical Engineering, Tamkang University,Tamsui, Taiwan 251, R.O.C.2Metal Industries Research & Development Centre,Kaohsiung, Taiwan 811, R.O.C.AbstractAbehavior strategy of humanoid robot for obstacle avoidance based on four infrared sensors is proposed and implemented on an autonomous humanoid robot. A mechanical structure with 26 degrees of freedom is design so that an implemented small-size humanoid robot named TWNHR-III is able to accomplish five walking motions. Three walking experiments are presented to illustrate that the proposed biped structure lets TWNHR-III can move forward, turn, and slip. One electronic compass and four infrared sensors are mounted on TWNHR-III to obtain the head direction of the robot and detect obstacles, respectively. Based on the obtained information from these sensors, a decision tree method is proposed to decide one behavior from five movements: walk forward, turn right and left, and slip right and left. Two MATLAB simulations and one real experiment are presented to illustrate that the robot can avoid obstacles autonomously and go to the destination effectively.Key Words: Humanoid Robot, Autonomous Mobile Robot, Obstacle Avoidance, Decision Tree1. IntroductionAlthough the robot has been investigated for many years, there are still many issues to be studied, especially in the humanoid robots [1⎽4]. Hardware and software architectures,walking gait generation, and artificial intelligence are the main research fields of humanoid robots.Robot soccer games are used to encourage the researches on robotics and artificial intelligence (AI). Two international robot soccer associations, RoboCup [5] and FIRA[6], advance this research and hold the international competitions and the international symposiums. Robot soccer games are two teams constituted by several soccer robots to play soccer games under some size restrictions and rules. In the FIRA Cup event, several main categories are organized: the Mi cro-ro bot So ccer t ournament(MiroSot), the Simu lated ro bot So ccer t ournament (SimuroSot),the Robo t So ccer t ournament (RoboSot), and the Hu manoid ro bot So ccer t ournament (HuroSot). In the HuroSot category, the humanoid robot has to detect all information from the game field and decides its strategy by itself. There are many robots in the match field, so the robot must have the ability to avoid the collision with other robots and walk to an appropriate destination.Thus obstacle run is a competition category in the HuroSot league of FIRACup. The main idea of this competition category is used to test the ability of obstacle avoidance of the robot. In general, vision sensors, ultrasonic sensors, and infrared sensors are usually used todetect obstacles in the soccer game [7⎽11].In this paper, a mechanical structure with 26 degrees of freedom is design so that an implemented small-size humanoid robot named TWNHR-III (TaiWaN HumanoidRobot-III) is able to accomplish five walking motions:walk forward, turn right and left, and slip right and left. One digital electronic compass and four infrared sensors are installed on TWNHR-III. Based onthe information obtained from these sensors, a decision tree method is proposed to determine one behavior from these five movements in each decision so that TWNHR-III can avoid obstacles and go to a destination effectively.The rest of this paper is organized as follows: In Section 2, the system architecture of TWNHR-III is described.In Section 3, a decision tree method for obstacle avoidance is proposed and two simulation results and one practical test on TWNHR-III are described. In Section 4, some conclusions are made.2. System Architecture of TWNHR-IIIThe system architecture of TWNHR-III is described in this section. The height of TWNHR-III is 46 cm and the weight is 3.1 kg with batteries. The frameworks of TWNHR-III are mainly fabricated from aluminum alloy 5052 in order to realize the concepts of light weight, wear-resisting, high stiffness, and wide movable range.Each actuator system of the joint consists of a high torque and a gear. The rotating speed and rotating angle of each joint are designed based on the result of computer program. The mechanical structure and electronic structure of TWNHR-III are described as follows:2.1 Mechanical StructureMechanical structure design is the first step in the humanoid robot design. The degrees of freedom (DOFs) configuration for TWNHR-III is described in Figure 1,where 26 degrees of freedom are implemented and the rotational direction of each joint is defined by using the inertial coordinate system fixed on the ground. There are 2 degrees of freedom on the neck, 2 degrees of freedom on the waist and trunk, 8 degrees of freedom on the arm,and 14 degrees of freedom on the two legs. Aphotograph and some mechanical views of TWNHR-III are respectively described in Figure 2 and Figure 3.Human body mechanism basically comprises bones,joints, muscles, and tendons. It is impossible to replace all of the muscular-skeletal system by current mechanical and electronic components. Therefore, the primary goal of the humanoid robot mechanical design is to let the implemented robot can imitate equivalent human motion. A mechanical structure is designed and implemented so that the implemented humanoid robot can find the ball, walk forward, turn right and left, and slip right and left. The details of the development of the head,waist and trunk, arms, and legs are described as follows:2.1.1 HeadThe 3D mechanism design and DOFs diagram of the head are described in Figure 4, where the head of TWNHR-III has 2 degrees of freedom and each degree is described by the number in (b). The raw and pitch motions are implemented on the head so that it can turn right-and-left and up-and-down. Some corresponding behaviors between human and TWNHR-III in the joints of head are described in Table 1.2.1.2 Waist and TrunkThe 3D mechanism design and DOFs diagram of the waist and trunk are described in Figure 5, where each waist and trunk of TWNHR-III has 2 degrees of freedom and each degree is described by the number in (b). The waist and trunk are designed based on the concept that robot can adjust the trunk motions to compensate for the robot’s walk motion. Some corresponding behaviors between human and TWNHR-III in the joints of waist and trunk are described in Table 2.2.1.3 ArmsThe 3D mechanism design of the arms are described in Figure 6, where each arm of TWNHR-III has 4 degrees of freedom. The arms of the robot are designed based on some behaviors of human’sarms. For example,its arm can hold an object such as a ball. Some corresponding behaviors between human and TWNHR-III in the joints of arms are described in Table 3.2.1.4 LegsIn order to realize the normal walking motion of human,7 degrees of freedom are adopted to implement the joints of one leg. Leg is take great part weight of whole body, due to the knee joint. In order to improve the robust of the leg, two motors are designed and implemented in one knee joint. The 3D mechanism design and DOFs diagram of the legs are described in Figure 7, where each leg of TWNHR-III has 7 degrees of freedom and each degree is described by the number in (b). The legs are designed based on the concept that robot can accomplish the human walking motion. Some corresponding behaviors between human and TWNHR-III in the joints of legs are described in Table 4.2.2. Electronic StructureIn the electronic structure design for TWNHR-III,the system block diagram is described in Figure8, where 26 servomotors with high torques are used as the actuators of the robot. In order to build a fully autonomous vision based humanoid robot, a 16-bit DSP processor with a CMOS sensor is chosen to process the vision image of environment. The image of the field is captured by the CMOS sensor and the position information of the ball and goals is processed and extracted by the DSP processor.One electronic compass and four infrared sensors are mounted on TWNHR-III to obtain the head direction of the robot and detect obstacles, respectively. The installed positions and their detectable ranges of these four infrared sensors are described in Figure 9 and Figure 10, respectively.The electronic compass is mounted on the body to detect the head direction of the robot and the goal direction, respectively. The relative angle of goal direction and robot direction is shown in Figure 11. In the circuit design, the SoPC (System on a Programmable Chip) concept is applied and implemented on a FPGA chip to reduce the complexity of circuit design. The implemented FPGA chip can process the data obtained from the sensors and generate desired pulses to control the angles of servomotors. Many functions are implemented on the FPGAchip to process the data and control the robot so that the weight of the robot is reduced.2.3. Walking ExperimentsA mechanical structure with 26 degrees of freedom is design so that TWNHR-III is able to accomplish five walking motions: walk forward, turn right and left, and slip right and left. Its control method is based on the try and error method. In order to verify the effectiveness ofthe implemented humanoid robot, three basic walking skills: straight walk, turn, and slip are carried out on a horizontal even plane and described as follows:2.3.1 Straight WalkSome snapshots of straight walking of TWNHR-III are shown in Figure 12, where the distance between every white line is 5 cm. Every step of the straight walking is able to move forward 10 cm.2.3.2 TurnSome snapshots of left turning of TWNHR-III are shown in Figure 13, where the angle between every white line is 15 degrees. Each time of the robot turning is able to turn 30 degrees.2.3.3 SlipSome snapshots of right slipping of TWNHR-III are shown in Figure 14, where the distance between every white line is 5 cm. Every step of the robot slipping is able to slip 10 cm.From these experiment results, we can see that the proposed mechanical structure can let TWNHR-III move forward, turn, and slip effectively.3. Obstacle Avoidance3.1 Decision Tree MethodObstacle run is a competition category in the HuroSot league of FIRA Cup. As shown in Figure 15, there is a finish line marked on one side of the playing field. This side of the playing field is called the finish side. The opposite side of the playing field is called the start side. The two other sides are called side lines. Arobot has crossed the finish line when the robot crosses the finish plane and touches the ground in the end zone. During the obstacle run competition, the robot does not allow to touch any obstacles. The robot has to detect obstacles and the direction of the goal line. Adecision tree method based on four infrared sensors is proposed and described in Figure 16. The behavior output of the decision tree is the robot’s five basic motions including go forward, 30 degree right turn, 30 degree left turn, slip right, and slip left. Sixteen behavior situations and their corresponding movements are described in Table 5. The strategy will check the relative behavior from the decision tree before the robot move. In order to let the robot walk toward the goaldirection, the robot will adjust the robot direction to face the goal direction based on the electronic compass informationwhen he robot is in the safe situation (B16 situation).3.2 Simulation and Experiment ResultsIn order to illustrate the proposed method can successfully avoid obstacles and go to the destination,two MATLAB simulations and one real experiment are presented. Figure 17 and Figure 18 illustrate the obstacle avoidance ability of the robot by MATLAB simulation results. In Figure 17, there is one obstacle on the robot’s way to the goal line. When the robot detects the obstacle, the “slip right”behavior is made by the proposed decision tree method to avoid the obstacle based on the detected behavior situation B10. The robot keeps slipping to the right side, until there is no obstacle in front of the robot. When the detected behavior situation is changed from B10 to B16, the “move to goal line” behavior is made to let the robot walk toward the goal line. In Figure 18, there are two obstacles on the robot’s way to the goal line. The robot also chooses the behavior from the proposed behavior strateg y. At the location of “Safe point”,the robot is already in the safe situation. Therefore, the detected behavior situation is B16 to let the robot walk toward the goal line. As the robot moving forward, it detects the other obstacle. The “slip left” behavi or is made to avoid this obstacle based on the detected behavior situation B9. The detected behavior situation will change to B16 when the robot is away from this obstacle.The computer simulation results in Figure 17 andFigure 18 illustrate that the robot can effectively avoid obstacles and successfully arrive the goal line based on the proposed decision tree method. In the practical test, the proposed decision tree method implemented on the TWNHR-III in a real test ground is discussed. Six sequential image stills of TWNHR-III for a real experiment of obstacle avoidance are shown in Figure 19, where two obstacles are on the robot’s way to the goal line. Once TWNHR-III detects the obstacle via the infrared sensors, the robot will do an appropriate behavior to avoid obstacles. We can see that TWNHR-III can successfully avoid two obstacles by the proposed decision tree method.The soccer robot needs to play a soccer game autonomously. Playing soccer game is a good testplatform to verify the ability of the designed and implemented robot. There are many robots in thematch field, so the soccer robot must have the ability to avoid the collision with other robots and move to an appropriate destination. Thus the obstacle run is a competition category in the HuroSot league of FIRACup. Some basic walking experiments of TWNHR-III have been presented to illustrate that the proposed mechanical structure with 26 degrees of freedom can let TWNHR-III move forward, turn, and slip. Based on the obtained information from one compass and four infrared sensors installed on TWNHR-III, a decision tree method is proposed. Two MATLAB simulation results and one practical test on TWNHR-III have been presented to illustrate that the proposed decision tree method can let the robot effectively avoid obstacles and successfully go to the destination. One CMOS sensor is installed on TWNHR-III so that it can be a visionbased soccer robot to autonomously find a ball and kick a ball. Moreover, TWNHR-III won champion of the humanoid league in Taiwan Cup 2006. In the future, TWNHR-III will be used to investigate the walking gait and artificial intelligence. For example, some force sensors will be installed on TWNHR-III to study the biped walking control on even or uneven ground. More research on artificial intelligence will be carried on TWNHR-III to make it to be an intelligent robot.AcknowledgementThis research was supported in part by the National Science Council (NSC) of the Republic of China under contract NSC 95-2221-E-032-057-MY3 and the Metal Industries Research & Development Centre (MIRDC), Kaohsiung, Taiwan, Republic of China.References[1] Ogura, Y., Aikawa, H., Shimomura, K., Kondo, H.,Morishima, A., Lim, H. O. and Takanishi, A., “Development of a New Humanoid Robot WABIAN-2,”IEEE Int. Conf. on Robotics and Automation, pp. 835⎽840 (2006).[2] Hirai, K., Hirose, M., Haikawa, Y. and Takenaka, T.,“The Development of Honda Humanoid Robot,” IEEE Int. Conf. on Robotics and Automation, Vol. 2, pp. 1321⎽1326 (1998).[3] Kaneko, K., Kanehiro, F., Kajita, S., Hirukawa, H.,Kawasaki, T., Hirata, M., Akachi, K. and Isozumi, T.,“Humanoid Robot HRP-2,” IEEE Int. Conf. on Robotics and Automation, Vol. 2, pp. 1083⎽1090 (2004).[4] Lohmeier, S., Loffler, K., Gienger, M., Ulbrich, H. and Pfeiffer, F., “Computer System and Controlof Biped “Johnnie”,” IEEE Int. Conf. on Robotics and Automation, Vol. 4, pp. 4222⎽4227 (2004).[5] URL: [6] URL: [7] Borenstein, J. and Koren, Y., “Real-Time Obstacle Avoidance for Fact Mobile Robots,” IEEE Tran. On Systems, Man and Cybernetics, Vol. 19, pp. 1179⎽1187 (1989).[8] Crowley, J., “DynamicWorld Modeling for an Intelligent Mobile Robot Using a Rotating Ultra-Sonic Ranging Device,” IEEE Int. Conf. on Robotics and Automation,Vol. 2, pp. 128⎽135 (1985).[9] Rao, N. S. V., “Robot Navigation in Unknown Generalized Polygonal Terrains Using Vision Sensors,” IEEE Tran. on Systems, Man and Cybernetics, Vol. 25, pp. 947⎽962 (1995).[10] Innocenti, C., Mondino, G., Regis, P. and Sandini, G., “Trajectory Planning and Real-Time Control of an Autonomous Mobile Robot Equipped withVision and Ultrasonic Sensors,” IEEE/RSJ/GI Int. Conf. on Intelligent Robots and Systems, Vol. 3, pp. 1861⎽1866 (1994).[11] Wong, C. C., Cheng, C. T., Huang, K. H., Yang, Y. T., Chan, H. M. and Yin, C. S., “Me chanical Design of Small-Size Humanoid Robot TWNHR-3,” The 33rd Annual Conference of the IEEE Industrial Electronics Society, pp. 451⎽454 (2007).Manuscript Received: Jul. 27, 2007Accepted: Aug. 7, 2008258 Ching-Chang Wong et al.。
机器人模糊避障外文翻译
Autonomous robot obstacle avoidance using a fuzzy logic control schemeWilliam MartinSubmitted on December 4, 2009CS311 - Final Project1. INTRODUCTIONOne of the considerable hurdles to overcome, when trying to describe areal-world control scheme with first-order logic, is the strong ambiguity found in both semantics and evaluations. Although one option is to utilize probability theory in order to come up with a more realistic model, this still relies on obtaining information about an agent's environment with some amount of precision. However, fuzzy logic allows an agent to exploit inexactness in its collected data by allowing for a level of tolerance. This can be especially important when high precision or accuracy in a measurement is quite costly. For example, ultrasonic and infrared range sensors allow for fast and cost effective distance measurements with varying uncertainty. The proposed applications for fuzzy logic range from controlling robotic hands with six degrees of freedom1 to filtering noise from a digital signal.2 Due to its easy implementation, fuzzy logic control has been popular for industrial applications when advanced differential equations become either computationally expensive or offer no known solution. This project is an attempt to take advantage of these fuzzy logic simplifications in order to implement simple obstacle avoidance for a mobile robot. 2. PHYSICAL ROBOT IMPLEMENTATION2.1. Chassis and sensorsThe robotic vehicle's chassis was constructed from an Excalibur EI-MSD2003 remote control toy tank. The device was stripped of all electronics, gears, and extraneous parts in order to work with just the empty case and two DC motors for the tank treads. However, this left a somewhat uneven surface to work on, so high-density polyethylene (HDPE) rods were used to fill in empty spaces. Since HDPE has a rather low surface energy, which is not ideal for bonding with other materials, a propane torch was used to raise surface temperature and improve bonding with an epoxy adhesive.Three Sharp GP2D12 infrared sensors, which have a range of 10 to 80 cm, were used for distance measurements. In order to mount these appropriately, a 2.5 by 15 cm piece of aluminum was bent into three even pieces at 135 degree angles. This allows for the IR sensors to take three different measurements at 45 degree angles (right, middle, and left distances). This sensor mount was then attached to an HDPE rod with mounting tape and the rod was glued to the tank base with epoxy. Since the minimum distance that can be reliably measured with these sensors is 10 cm, the sensors were placed about 9 cm from the front of the vehicle. This allowed measurements to be taken very close to the front of the robot.2.2. ElectronicsIn order to control the speed of each motor, pulse-width modulation (PWM) was usedto drive two L2722 op amps in open loop mode (Fig. 1). The high input resistance of these ICs allow for the motors to be powered with very little power draw from the PWM circuitry. In order to isolate the motor's power supply from the rest of the electronics, a 9.6 V NiCad battery was used separately from a standard 9 V that demand on the op amps led to a small amount of overheating during continuous operation. This was remedied by adding small heat sinks and a fan to the forcibly disperse heat.Fig. 1. The control circuit used for driving each DC motor. Note that the PWM signal was between 0 and 5 V.2.3. MicrocontrollerComputation was handled by an Arduino Duemilanove board with anATmega328 microcontroller. The board has low power requirements and modifications. In addition, it has a large number of prototyping of the control circuit and based on the Wiring language. This board provided an easy and low-cost platform to build the robot around.3. FUZZY CONTROL SCHEME FORIn order to apply fuzzy logic to the robot to interpret measured distances. While the final algorithm depended critically on the geometry of the robot itself and how it operates, some basic guidelines were followed. Similar research projects provided both simulation results and ideas for implementing fuzzy control.3,4,53.1. Membership functionsThree sets of membership functions were created to express degrees of membership for distances, translational speeds, and rotational speeds. This made for a total of two input membership functions and eight output membership functions (Fig.2). Triangle and trapezoidal functions were used exclusively since they are quick to compute and easy to modify. Keeping computation time to a minimum was essential so that many sets of data could be analyzed every second (approximately one every 40 milliseconds). The distance membership functions allowed the distances from the IR sensors to be quickly "fuzzified," while the eight speed membership functions converted fuzzy values back into crisp values.3.2.Rule baseOnce the input data was fuzzified, the eight defined fuzzy logic rules (Table I) were executed in order to assign fuzzy values for translational speed and rotation. This resulted in multiple values for the each of the fuzzy output components. It was then necessary to take the maximum of these values as the fuzzy value for each component. Finally, these fuzzy output values were "defuzzified" using themax-product technique and the result was used to update each of the motor speeds.(a)(b)(c)Fig. 2. The membership functions used for (a) distance, (b) translation speed, and (c) rotational speed. These functions were adapted from similar work done in reference 3.4. RESULTSThe fuzzy control scheme allowed for the robot to quickly respond to obstacles it could detect in its environment. This allowed it to follow walls and bend around corners decently without hitting any obstacles. However, since the IR sensors' measurements depended on the geometry of surrounding objects, there were times when the robot could not detect obstacles. For example, when the IR beam hit asurface with oblique incidence, it would reflect away from the sensor and not register as an object. In addition, the limited number of rules used may have limited the dynamics of the robot's responses. Some articles suggest as many as forty rules6 should be used, while others tend to present between ten and twenty. Since this project did not explore complex kinematics or computational simulations of the robot, it is difficult to determineexactly how many rules should be used. However, for the purposes of testing fuzzy logic as a navigational aide, the eight rules were sufficient. Despite the many problems that IR and similar ultrasonic sensors have with reliably obtaining distances, the robustness of fuzzy logic was frequently able to prevent the robot from running into obstacles.5. CONCLUSIONThere are several easy improvements that could be made to future iterations of this project in order to improve the robot's performance. The most dramatic would be to implement the IR or ultrasonic sensors on a servo so that they could each scan a full 180 degrees. However, this type of overhaul may undermine some of fuzzy logic's helpful simplicity. Another helpful tactic would be to use a few types of sensors so that data could be taken at multiple ranges. The IR sensors used in this experiment had a minimum distance of 10 cm, so anything in front of this could not be reliably detected. Similarly, the sensors had a maximum distance of 80 cm so it was difficult to react to objects far away. Ultrasonic sensors do offer significantly increased ranges at a slightly increased cost and response time. Lastly, defining more membership functions could help improve the rule base by creating more fine tuned responses. However, this would again increase the complexity of the system.Thus, this project has successfully implemented a simple fuzzy control scheme for adjusting the heading and speed of a mobile robot. While it is difficult to determine whether this is a worthwhile application without heavily researching other methods, it is quite apparent that fuzzy logic affords a certain level of simplicity in the design of a system. Furthermore, it is a novel approach to dealing with high levels of uncertainty in real-world environments.6. REFERENCES1 Ed. M. Jamshidi, N. Vadiee, and T. Ross, Fuzzy logic and control: software and hardware applications, (Prentice Hall: Englewood Cliffs, NJ) 292-328.2 Ibid, 232-261.3 W. L. Xu, S. K. Tso, and Y. H. Fung, "Fuzzy reactive control of a mobile robot incorporating a real/virtual target switching strategy," Robotics and Autonomous Systems, 23(3), 171-186 (1998).4 V. Peri and D. Simon, “Fuzzy logic control for an autonomous robot,” 2005 Annual Meeting of the North American Fuzzy Information Processing Society, 337-342 (2005).5 A. Martinez, E. Tunstel, and M. Jamshidi, "Fuzzy-logic based collision-avoidance for a mobile robot," Robotica, 12(6) 521–527 (1994).6 W. L. Xu, S. K. Tso, and Y. H. Fung, "Fuzzy reactive control of a mobile robot incorporating a real/virtual target switching strategy," Robotics and AutonomousSystems, 23(3), 171-186 (1998).采用模糊逻辑控制使自主机器人避障设计威廉马丁提交于2009年12月4日CS311 -最终项目1 引言其中一个很大的障碍需要克服,当试图用控制逻辑一阶来描述一个真实世界设计在发现在这两个语义评价中是个强大的模糊区。
机器人设计外文翻译---新型的机器人可在数百公尺深的水底残骸间自由穿梭游览
英文原文The Abyss Transit System- James Cameron commissions the making of robots for a return to theTitanicBy Gary StixAt the beginning of the movie that made Leonardo DiCaprio a megastar, a camera-toting unmanned robot ventured into a cavernous hole in the wreck that sits on the bottom of the Atlantic, 12,640 feet from the surface. The 500-pound vehicle, christened Snoop Dog, could move only about 30 feet along a lower deck, hampered by its bulky two-inch-diameter tether hitched to a submarine that waited above. The amount of thrust needed to move its chunky frame stirred up a thick cloud. “The vehicle very quickly silted out the entire place and made imaging impossible,” director James Cameron recalls.But the eerie vista revealed by Snoop Dog on that 1995 expedition made Cameron hunger for more. He vowed to return one day with technology that could negotiate anyplace within the Titanic's interior.In the past six months two documentaries—one for IMAX movie theaters called Ghosts of the Abyss, the other, Expedition: Bismarck, for the DiscoveryChannel—demonstrated the fruits of a three-year effort that Cameron financed with $1.8 million of his own money to make this vision materialize. The payoff was two 70-pound robots, named after Blues Brothers Jake and Elwood, that had the full run of two of the world's most famous wrecks, the Titanic and the Bismarck, which they visited on separate expeditions.The person who took Jake and Elwood from dream to robot is Mike Cameron, James's brother, an aerospace engineer who once designed missiles and who also possesses a diverse background as a helicopter pilot, stunt photographer and stuntman. (Remember the corpse in the movie The Abyss, from whose mouth a crab emerges?) Giving the remotely operated vehicles freedom of movement required that they be much smaller than Snoop Dog and that the tether's width be tapered dramatically so as not to catch on vertical ship beams.Mike Cameron took inspiration from the wire-guided torpedoes used by the military that can travel for many miles. His team created vehicles operable to more than 20,000 feet (enough to reach as much as 85 percent of the ocean floor). The dimensions of the front of the robot are 16 inches high by 17 inches across, small enough to fit in a B deck window of the Titanic. The bots have an internal battery so that they do not need to be powered through a tether. Instead the tether—fifty-thousandths of an inch in diameter—contains optical fibers that relaycontrol signals from a manned submersible vehicle hovering outside and that also send video images in the other direction. The tether pays out from the robot, a design that prevents it from snagging on objects in the wreck.James Cameron thought the project would be a straightforward engineering task, not much harder than designing a new camera system. “This turned out to be a whole different order of magnitude,” he says. “There was no commercial off-the-shelf hardware that woul d work in the vehicles. Everything had to be built from scratch.” If the team had known this early on, he added, “we wouldn't have bothered.” Water pressure on the cable that carried the optical fibers could create microscopic bends in the data pipe, completely cutting off the control signals from the submersibles. Dark Matter in Valencia, Calif. (Mike Cameron's company), had to devise a fluid-filled sheath around the fiber to displace the minuscule air pockets in the cable that could lead to the microbending.To save weight, the frame—similar to a monocoque body of a race car—was made up of small glass hollow spheres contained in an epoxy matrix. The thruster contained a large-diameter, slowly rotating blade with nozzles that diffused the propulsive flow, minimizing the churning that would otherwise disturb the caked silt.A high-resolution video camera, along with an infrared camera for navigation, was placed in the front of the craft along with three light-emitting-diode arrays for fill lighting and two quartz halogen lamps for spotlighting.The winter of 2001 marked a critical juncture. It was six months before dives to the Titanic could be safely attempted, and James had to determine whether to proceed or wait another year. “Mike was really, really ne gative on the idea, but I decided to go for it,” the director says. He felt he couldn't afford to wait longer and thought that a fixed deadline would focus the engineering staff at Dark Matter. Forhis part, Mike was contending with an unending series of de sign challenges. “It was such an overwhelming set of problems that I had very little confidence that certain parts would be solvable in the time we had,” Mike says.A few weeks before the dives commenced in the summer of 2001, the robots' lithium sulfur dioxode-based batteries caught fire while being tested in a pressure tank, destroying what was to have been a third robot. Mike wanted to delay the dives, but James found a supplier of another type of lithium battery and pressed ahead.At the dive site, Jake and Elwood took starring roles with their 2,000-foot tethers, exploring for the first time in about 90 years remote parts of the ships, including the engine room, the firemen's mess hall and the cabins of first-class passengers—even focusing in on a bowler hat, a brass headboard and an intact, upright glass decanter. The images lack the resolution and novel quality of the high-definition, three-dimensional IMAX images, the other major technological innovation of Ghostsof the Abyss. Jake and Elwood's discoveries, however, draw the viewers' interest because of what they convey of the Titanic's mystique. “You actually feel like you're out there in the wreck,” Mike says. He remembers his brother piloting the robots with the helicopter stick that had been installed in the Russian submersible from which the robots were launched. “Jim ended up being a cowboy pilot,” Mike says. “He was far more aggressive with the system than I was.”One scene in Ghosts of the Abyss reveals the tension that sometimes erupted between the brothers. James contemplates moving one of the robots through a cabin window that is still partially occluded by a shard of glass that could damage the vehicle or cut the data tether. When James declares that he is going to take Jake in, moviegoers can hear Mike pleading with his brother not to do it, ultimately relenting once the bot has negotiated the opening.The decision to install a new type of battery at the last minute came to haunt the expedition; Elwood's lithium-polymer battery ignited while in the bowels of the ship. James manipulated the remaining robot into the Titanic to perform a rescue operation by hooking a cord to the grill of the dead bot and towing it out. At the surface—on the deck of the Russian scientific vessel the Keldysh, from which the two submarines carrying Jake and Elwood to the Titanic were launched—Mike rebuilt Elwood with a backup battery. During the next dive, the robot caught fire again while it was still mounted on the submarine, endangering the crew. Finally, Mike worked for an 18-hour stretch to adapt a lead-acid gel battery used for devices onboard the mother ship into a power source for Elwood, enabling the expedition to continue.The bots, now fitted with a new, nonflammable battery that Mike designed, may find service beyond motion pictures. The U.S. Navy has funded Dark Matter to help it assess the technology for underwater recovery operations of ships or aircraft. The bots also have potential for scientific exploration of deep-sea trenches. After traveling to the Titanic and the Bismarck, the team went on to probe mid-Atlantic hydrothermal vents, discovering mollusks in a place where scientists had never encountered them before. As adventure aficionados, the brothers speculate that a descendant of Jake and Elwood might even be toted on a mission to Europa, one of Jupiter's moons, to investigate the waters that are suspected to exist below its icy shell. The Cameron siblings, who tinkered with home-built rafts and rockets as children in Ontario near Niagara Falls, hope to be around long enough to witness their robotic twins go from the bottom of the ocean to the depths of space.中文译文穿越深渊的机器--新型的机器人可在数百公尺深的水底残骸间自由穿梭游览作者╱斯蒂克斯( Gary Stix )曾一举捧红超级巨星李奥纳多狄卡皮欧的电影「铁达尼号」中,片头是一台无人驾驶的遥控装置,携带着摄影机深入大西洋,在3852公尺深的铁达尼号残骸里冒险的画面。
智能机器人外文翻译
RobotRobot is a type of mechantronics equipment which synthesizes the last research achievement of engine and precision engine, micro-electronics and computer, automation control and drive, sensor and message dispose and artificial intelligence and so on. With the development of economic and the demand for automation control, robot technology is developed quickly and all types of the robots products are come into being. The practicality use of robot products not only solves the problems which are difficult to operate for human being, but also advances the industrial automation program. At present, the research and development of robot involves several kinds of technology and the robot system configuration is so complex that the cost at large is high which to a certain extent limit the robot abroad use. To development economic practicality and high reliability robot system will be value to robot social application and economy development.With the rapid progress with the control economy and expanding of the modern cities, the let of sewage is increasing quickly: With the development of modern technology and the enhancement of consciousness about environment reserve, more and more people realized the importance and urgent of sewage disposal. Active bacteria method is an effective technique for sewage disposal,The lacunaris plastic is an effective basement for active bacteria adhesion for sewage disposal. The abundance requirement for lacunaris plastic makes it is a consequent for the plastic producing with automation and high productivity. Therefore, it is very necessary to design a manipulator that can automatically fulfill the plastic holding.With the analysis of the problems in the design of the plastic holding manipulator and synthesizing the robot research and development condition in recent years, a economic scheme is concluded on the basis of the analysis of mechanical configuration, transform system, drive device and control system and guided by the idea of the characteristic and complex of mechanical configuration, electronic, software and hardware. In this article, the mechanical configuration combines the character of direction coordinate and the arthrosis coordinate which can improve the stability and operation flexibility of the system. The main function of the transmission mechanism is to transmit power to implement department and complete the necessary movement. In this transmission structure, the screw transmission mechanism transmits the rotary motion into linear motion. Worm gear can give vary transmissionratio. Both of the transmission mechanisms have a characteristic of compact structure. The design of drive system often is limited by the environment condition and the factor of cost and technical lever. 'The step motor can receive digital signal directly and has the ability to response outer environment immediately and has no accumulation error, which often is used in driving system. In this driving system, open-loop control system is composed of stepping motor, which can satisfy the demand not only for control precision but also for the target of economic and practicality. on this basis, the analysis of stepping motor in power calculating and style selecting is also given.The analysis of kinematics and dynamics for object holding manipulator is given in completing the design of mechanical structure and drive system. Kinematics analysis is the basis of path programming and track control. The positive and reverse analysis of manipulator gives the relationship between manipulator space and drive sp ace in position and speed. The relationship between manipulator’s tip position and arthrosis angles is concluded by coordinate transform method. The geometry method is used in solving inverse kinematics problem and the result will provide theory evidence for control system. The f0unction of dynamics is to get the relationship between the movement and force and the target is to satisfy the demand of real time control. in this chamfer, Newton-Euripides method is used in analysis dynamic problem of the cleaning robot and the arthrosis force and torque are given which provide the foundation for step motor selecting and structure dynamic optimal ting.Control system is the key and core part of the object holding manipulator system design which will direct effect the reliability and practicality of the robot system in the division of configuration and control function and also will effect or limit the development cost and cycle. With the demand of the PCL-839 card, the PC computer which has a. tight structure and is easy to be extended is used as the principal computer cell and takes the function of system initialization, data operation and dispose, step motor drive and error diagnose and so on. A t the same time, the configuration structure features, task principles and the position function with high precision of the control card PCL-839 are analyzed. Hardware is the matter foundation of the control. System and the software is the spirit of the control system. The target of the software is to combine all the parts in optimizing style and to improve the efficiency and reliability of the control system. The software design of the object holding manipulator control system is divided into several blocks such assystem initialization block, data process block and error station detect and dispose model and so on. PCL-839 card can solve the communication between the main computer and the control cells and take the measure of reducing the influence of the outer signal to the control system.The start and stop frequency of the step motor is far lower than the maximum running frequency. In order to improve the efficiency of the step motor, the increase and decrease of the speed is must considered when the step motor running in high speed and start or stop with great acceleration. The increase and decrease of the motor’s speed can be controlled by the pulse frequency sent to the step motor drive with a rational method. This can be implemented either by hardware or by software. A step motor shift control method is proposed, which is simple to calculate, easy to realize and the theory means is straightforward. The motor' s acceleration can fit the torque-frequency curve properly with this method. And the amount of calculation load is less than the linear acceleration shift control method and the method which is based on the exponential rule to change speed. The method is tested by experiment.At last, the research content and the achievement are sum up and the problems and shortages in main the content are also listed. The development and application of robot in the future is expected.机器人机器人是典型的机电一体化装置,它综合运用了机械与精密机械、微电子与计算机、自动控制与驱动、传感器与信息处理以及人工智能等多学科的最新研究成果,随着经济的发展和各行各业对自动化程度要求的提高,机器人技术得到了迅速发展,出现了各种各样的机器人产品。
介绍智能家居机器人的英语作文
介绍智能家居机器人的英语作文Smart Home Robots: The Future of Domestic AssistanceIn the realm of modern technology, the concept of a smart home has become increasingly prevalent, and at the heart of this innovation lies the smart home robot. These intelligent machines are designed to revolutionize the way we interactwith our living spaces, making our lives more convenient, efficient, and enjoyable.Smart home robots are equipped with advanced artificial intelligence that allows them to perform a multitude of tasks. From simple chores such as cleaning and tidying up to more complex tasks like cooking and laundry, these robots are programmed to handle a wide array of household duties. They can also monitor the home's environment, adjusting the temperature, lighting, and security systems to suit the preferences and schedules of the occupants.One of the most impressive aspects of smart home robotsis their ability to learn and adapt. Over time, they can become familiar with the routines and preferences of the household members, making them increasingly efficient intheir tasks. They can also integrate with other smart devices in the home, creating a seamless and interconnected ecosystem that can be controlled remotely via a smartphone or voice commands.Security is another significant feature of smart home robots. They can be programmed to detect unusual activities and alert the homeowner or the authorities in case of any potential threats. With built-in cameras and sensors, these robots can provide a constant vigil over the home, ensuring the safety of its inhabitants.Moreover, smart home robots are not just limited to physical tasks. They can also serve as personal assistants, providing reminders, scheduling appointments, and even offering companionship. With natural language processing capabilities, these robots can engage in conversations, answer questions, and provide information on a wide range of topics.The integration of smart home robots into our daily lives is a testament to the rapid advancements in technology. As these machines continue to evolve, they are poised to become an indispensable part of our homes, offering unparalleled convenience and a level of domestic assistance that was once the stuff of science fiction.In conclusion, smart home robots represent a significant leap forward in home automation and personal assistance. As they become more sophisticated and widely adopted, it is clear that these robots will play an increasingly important role in shaping the future of our living environments.。
智能自动移动机器人系统研究中英文外文文献翻译
本科毕业设计(论文)中英文对照翻译(此文档为word格式,下载后您可任意修改编辑!)原文The investigation of an autonomous intelligent mobile robot systemfor indoor environment navigationS KarelinAbstractThe autonomous mobile robotics system designed and implemented for indoor environment navigation is a nonholonomic differential drive system with two driving wheels mounted on the same axis driven by two PID controlled motors and two caster wheels mounted in the front andback respectively. It is furnished with multiple kinds of sensors such as IR detectors ,ultrasonic sensors ,laser line generators and cameras,constituting a perceiving system for exploring its surroundings. Its computation source is a simultaneously running system composed of multiprocessor with multitask and multiprocessing programming. Hybrid control architecture is employed on the rmbile robot to perform complex tasks. The mobile robot system is implemented at the Center for Intelligent Design , Automation and Manufacturfing of City University of Hong Kong.Key words:mobile robot ; intelligent control ; sensors ; navigation IntroductionWith increasing interest in application of autonomous mobile robots in the factory and in service environments,many investigations have been done in areas such as design,sensing,control and navigation,etc. Autonomousreaction to the real wand,exploring the environment,follownng the planned path wnthout collisions and carrying out desired tasks are the main requirements of intelligent mobile robots. As humans,we can conduct these actions easily. For robots however,it is tremendously difficult. An autonomous mobile robot should make use of various sensors to sense the environment and interpret and organize the sensed information to plan a safe motion path using some appropriate algorithms while executing its tasks. Many different kinds of senors havebeen utilized on mobile robots,such as range sensors,light sensors,force sensors,sound sensors,shaft encoders,gyro scope s,for obstacle awidance,localizatio n,rmtion sensing,navigation and internal rmnitoring respectively. Many people use infrared and ultrasonic range sensors to detect obstacles in its reaching ser range finders are also employed in obstacle awidance behavior of mobile robots in cluttered space.Cameras are often introduced into the vision system for mobile robot navigation. Although many kinds of sensors are available,sensing doesn’t mean perceiving. The mechanical shape and driving type are commonly first taken into consideration while implementing a rmbile robot. A robot’s shape can have a strong impact on how robust it is,and DC serve rmtors or stepOper motors are often the two choices to employ as actuators. The shape of a robot may affect its configurations of components,ae sthetics,and even the movement behaviors of the robot. An improper shape can make robot run a greater risk of being trapped in a cluttered room or of failing to find its way through a narrow space. We choose an octahedral shape that has both advantages of rectangular and circular shapes,and overcomes their drawbacks. The framework of the octahedral shaped robot is easy to make,components inside are easily arrange and can pass through narrow places and rotate wrath corners and nearby objects,and is more aesthetic in appearance. The perception subsystem accomplishes the task of getting various data from thesurroundings,including distance of the robot from obstacles,landmarks,etc.Infrared and ultrasonic range sen}rs,laser rangefinders and cameras are utilized and mounted on the rmbile robot to achieve perception of the environment. These sensors are controlled independently by some synchronously running microprocessors that are arranged wrath distributive manner,and activated by the main processor on which a supervising program runs. At present,infrared and ultranic sensors,laser rangefinders are programmed to detect obstacles and measure distance of the robot from objects in the environment,and cameras are programmed for the purpose of localization and navigation.The decision-making subsystem is the most important part of an intelligent mobile robot that organizes and utilizes the information obtained from the perception subsystem. It obtains reasonable results by some intelligent control algorithm and guides the rmbile robot. On our mobile robotic system intelligence is realized based on behaviourism and classical planning principles. The decision-making system is composed of twa levels global task planning based on knowledge base and map of working enviro nment,reactive control to deal with the dynamic real world. Reaction tasks in the decision-making system are decomposed into classes of behaviors that the robot exhibits to accomplish the task. Fuzzy logic is used to implement some basic behaviors. A state machine mechanism is applied to coordinate different behaviors. Because manykinds of electronic components such as range sensors,cameras,frame grabbers,laser line generators,microprocessors,DC motors,encoders,are employed on the mobile robot,a power source must supply various voltage levels which should are stable and have sufficient power. As the most common solution to power source of mobile robots,two sealed lead acid batteries in series writh 24 V output are employed in our mobile robot for the rmtor drive components and electronic components which require 24 V,15V,士12V,+9V,士5V,variously. For the conversion and regulation of the voltage,swritching DC DC converters are used because of their high efficiency,low output ripple and noise,and wride input voltage range. Three main processors are Motorola MC68040 based single board computers on which some supervisory programs and decision-making programs run. These MC68040 boards run in parallel and share memory using a VMEbus. Three motorola MC68HC11 based controllers act as the lower level controllers of the infrared and ultranic range senors,which communicate with the main processors through serial ports. The multi-processor system is organized into a hierarchical and distributive structure to implement fast gathering of information and rapid reaction. Harmony,a multiprocessing and multitasking operating system for real-time control,runs on the main processors to implement multiprocessing and multitasking programming. Harmony is a runtime only environment and program executions are performed by downloadingcrosscompiled executable images into target processors. The hardware architecture of the mobile robot is shown in Fig. Robots control For robots,the three rmst comrmn drive systems are wheels,tracks and legs. Wheeled robots are mechanically simpler and easier to construct than legged and tracked systems that generally require more complex and heavier hardware,so our mobile robot is designed as a wheeled robot. For a wheeled robot,appropriate arrangements of driving and steering wheels should be chosen from differential,synchro,tricycle,and automotive type drive mechanisms. Differential drives use twa caster wheels and two driven wheels on a common axis driven independently,which enable the robot to move straight,in an arc and turn in place. All wheels are rotate simultaneously in the synchro drive;tricycle drive includes two driven wheels and one steering wheel;automobile type drive rotates the front twa wheels together like a car. It is obvious that differential drive is the simplest locomotion system for both programming and construction.However,a difficult problem for differentially driven robots is how to make the robot go straight,especially when the motors of the two wheels encounter different loads. To follow a desired path,the rmtor velocity must be controlled dynamically. In our mobile robot system a semv motor controller is used which implements PID control.Ibwer amplifiers that drive the motors amplify the signals from each channel of serwcontroller. Feedback is provided by shaft encoders on the wheels.The block diagram of the motor control electronic components are shown in Fig. 2,and the strategy of two wheel speed control based PID principle is illustrated in Fig.3. Top loop is for tracking the desired left motor velocity;bottom loop for tracking right motor velocity;Integral loop ensures the robot to go straight as desired and controls the steering of the robot. This is a simple PI control that can satisfy the general requirements.Sensing subsystemSensor based planning makes use of sensor information reflecting the current state of the environment,in contrast to classical planning,which assumes full knowledge of the environment prior to planning. The perceptive subsystem integrates the visual and proximity senors for the reaction of the robot. It plays an important role in the robot behavioral decision-making processes and motion control. Field of view of perceptive subsystem is the first consideration in the design of the sensing system. Fneld of view should be wide enough with sufficient depth of field to understand well the robot’s surroundings. Multiple sensors can provide information that is difficult to extract from single sensor systems. Multiple sensors are complementary to each other,providing a better understanding of the work environment. Omnidirectional sensory capability is endowed on our mobile robot. When attempting to utilize multiple senors,it must be decided how many different kinds of sensorsare to be used in order to achieve the desired motion task,both accurately and economically.Ultrasonic range sensing is an attractive sensing rmdalityfor mobile robots because it is relatively simple to implement and process,has low cost and energy consumption. In addition,high frequencies can be used to minimize interference from the surrounding environment. A special purpose built infrared ranging system operates similar to sonar,determining the obstacle’s presence or absence and also the distance to an object. For detecting smaller obstacles a laser rangefinder can be used. It can be titled down to the ground to detect the small objects near the robot. Identifying robot self position and orientation is a basic behavior that can be part of high level complex behaviors. For localizing a dead reckoning method is adopted using the output of shaft encoders. This method can have accumulated error on the position and orientation. Many external sensors can be used for identification of position and orientation. Cameras are the most popular sensor for this purpose,because of naturally occurring features of a mom as landmarks,such as air conditioning system,fluorescent lamps,and suspended ceiling frames.Any type of sensor has inherent disadvantages that need to be taken into consideration. For infrared range senors,if there is a sharply defined boundary on the target betweendifferent materials,colors,etc.,the sensor may not be able to calculate distance accurately. Some of these problemscan be avoided if due care is taken when installing and setting up the sensor. Crosstalk and specular reflection are the two main problems for ultrasonic sensors. The firing rates,blanking intervals,firing order,and timeouts of the ultrasonic sensor system can configured to improve performance. Laser ranging systems can fail to detect objects made of transparent materials or with poor light reflectivity. In this work,we have chosen range sensors and imaging sensors as the primary source of information. The range sensors employed include ultrasonic sensors and short and long range infrared sensors with features above mentioned. The imaging sensors comprise gray scale video cameras and laser rangefinders. Twenty-four ultrasonic sensors are arranged in a ring with a separation angle of 15 degrees on our mobile robot to detect the objects in a 3600 field of view. This will allow the robot to navigatearound an unstructured environment and to construct ac curate sonar maps by using environmental objects as naturally occurring beacons. With the sonar system we can detect objects from a minimum range of 15 cm to a maximum range of 10. 0 m. Infrared range sensors use triangulation,emitting an infrared spot from an emitter,and measuring the position of the imaged spot with a PSD (position sensitive detector).Since these devices use triangulation,object color,orientation,and ambient light have greater effect on sensitivity rather than accuracy. Since the transmission signal is light instead of sound,we may expect a dramatically shortercycle time for obtaining all infrared sensor measurements. A getup of 16 short and a group of 16 long infrared sensors are mounted in twa rings with equal angular Generally speaking,the robot motion closed control loops comprising sensing,planning,and acting should take very short cycle times,so a parallel computation mechanism is employed in our mobile robot based on multiprocessor. Usually we can make events run in parallel on single microprocessor or multiprocessor by twa methods,multitasking and multiprocessing. Well known multitasking OS is like Microsoft window' 95 and UNIX OS that can make multitask run in parallel on a sequential machine by giving a fraction of time to each behavior looply. In fact,multitask mechanism just simulates the effect of all events running simultaneously. Running all events on multiprocessor can realize true parallelism. In our mobile robot,using Harmony OS both multitasking and multiprocessing programming is implemented on multiprocessor (MC68040 processors) which share memories and communicate each other by VMEbus. Harmony allows creating many tasks as desired which can be map toseveral microprocesors and run in parallel .In addition,tasks written in C run on MC68040 can activate the assembly code in the MC68HC11 SBC which control infrared and ultrasonic sensors and get distances dates. These SBC run simultaneously with MC68040 processors. An instance of an implemented task structure is shown in Fng. 5.Some experiments,such as following lines,avoiding obstacles and area filling have been carried out on the rmbile system to demonstrates its real-time reactions to the working surroundings and robustness of the system. ConclusionWe have described the implementation of a intelligent mobile robot testbed for autonomous navigation in indoor environments and for investigation of relative theories and technologies of intelligent systems. The robot is furnished with range sensors,laser line generators and vision system to perceive its surroundings. Parallel computation based on multiprocessor is employed in the mobile robot to improve its power of reasoning and response. Low level processing and sensor control is carried out with low cost dedicated microcontrollers. A task based real-time operating system supports a variety of different control structures,allowing us to experiment with different approaches. The experiments indicate the effectiveness of the mobile robot system .The platform has been used for experimenu and research such as sensor data fusion,area filling,feedback control,as well as artificial intelligence.译文基于室内环境导航的智能自动移动机器人系统研究卡若琳摘要这种为室内境导航条件下设计生产的自主移动机器人系统是一个不完整的差速传动系统,它有两个安装在同一轴上通过两个PID控制的电机驱动的驱动轮和两个分别安装在前部和后部的脚轮。
工业机器人毕业设计外文翻译
外文资料:INDUSTRIAL ROBOTSMechatronicsThe success of industries in manufacturing and selling goods in a world market increasingly depends upon an ability to integrate electronics and computing technologies into a wide range of primarily mechanical products and processes. The performance of many current products-cars, washing machines, robots or machine tools-and their manufacture depend on the capacity of industry to exploit developments in technology and to introduce them at the design stag into both products and manufacturing processes. The results so that the whole industrial system to produce a cheaper and easier than in the past, more reliable, more powerful manufacturing technology, this intense competition, leading to the original electronic engineering and mechanical engineering have been gradually difference among the various disciplines with engineering design replaced with the mutual penetration, resulting in a mechanical and electrical integration, or mechatronics.In this competitive environment, the success of products and technologies are those that effectively combine the electronic and mechanical products, but not the main reason is the absence of a successful application of electronic technology. General product innovation in machine-building industry, often starting from the mechanical hardware design, but in order to achieve vision, from the initial stages of the design process must take full account of electronic technology, control engineering and computer technology. Research from the machinery and electronics to engineering design, the key is through the mechanics and electronics hidden boundaries, put them together, it is understood today the key to this transformation took place.To be successful, early in the design of the study need to establish the concept of mechatronics, when the specific program has not yet formed, so there is choice. In this way, design engineers, especially mechanical design engineers will be able to make a decision too quickly to avoid falling into the stereotypes and reduce productivity.Fully study the market trend, we will find electromechanical integration with a design, will lead to a revival of the field, such as high-speed textile machines, measurement and measurement systems, and automatic test equipment, integrated circuits Xiang kind of special equipment. In many cases sub ah, the emerging field of production and recovery are often formed by the embedded microprocessor electronics and basic mechanical system caused by the integrated and enhanced processing capacity.Flexibility of the manufacturing process the request resulted in the production of flexible operating system concepts in this system, many components such as computer numerical control machine tools, robots and automatic guided vehicles, etc. associated with joint production, exchange of information between them through Local Area Network.The products so far, most do not realize the design of electromechanical integration of diversity for the engineering sudden opportunity. The final product sold to customers is the essence of our revenue sources, which may begin the application is the date the new mechatronic products and provide enhanced functionality important difference between traditional products.The following examples may illustrate that the traditional products: Automatic transmission control engine and automatic control of the development of engines and transmissions tend to reduce the radiation, save fuel and time by preventing excessive speed and the use of the fuel flow can be adjusted to avoid false-driven gear and so on.Power-driven tools of modern power-driven tools, such as drill bits you can provide a variety of functions, including speed and torque control, reverse action and acceleration control.The new examples of mechatronic products are as follows:Standard components assembled a traditional industrial robot because of structural problems often many restrictions. Using a number of structural parts and drive, coupled with the central processor can be made by the standard components to assemble the robot system, so users can assemble to meet their own needs various robots.Video and CD player, video and CD player laser head is equipped with sophisticated, you can read the digital information on the disk. Withmicroprocessor control system can provide multi-track selection, scan preview and many other features.The above examples show that the purpose of the use of machinery is the continuous improvement of electronic consumer goods, not to keep consumer prices lower. Machinery and electronics products provide solutions to specific problems of the ideal way to use a low-cost element or standards.The personal computer controller and programmable logic controllerEarly machine tools and robots in the controller's function is to store and perform some simple procedures for the implementation of the tool or device with a predetermined speed to generate the required movement. Since 1981, IBM's first since the emergence of personal computers, many manufacturers produce microprocessors based on its so-called. Through the main memory and secondary storage devices exchange data, which allows users to use than the system microprocessor to provide the actual storage space for more storage space programming. It is this processing power and storage efficiency had a dramatic impact, making more and more industrial sectors to PC, for data acquisition and control applications. In addition to handling capabilities, PC machine control applications as a key component of many other advantages. These advantages are:(1) choice of application software more than a dedicated controller.(2) Select the tools to improve application efficiency and room for more.(3) The PC is available in a variety of forms ranging from a single card, a portable,a desktop and ruggedized industrial version for use on the factory floor.(4) bus architecture with multiple expansion slots, digital and analog input / output cards can be produced by several manufacturers.(5) special machine or a small computer than a more flexible, depending on the application can be very convenient for a variety of configurationsPC, data acquisition and control device may be an additional external and interest rates through, or it may be a plug-in board. Typically add a separate external rack, the internal packaging has to provide power to the host through the serial or parallel data communications cable. A variety of standard format modules can be inserted in the rack as needed.PC, data acquisition There are basically two ways. The first use of analog /digital conversion card connected directly with the host backplane. Conversion cards generally do port address can be any support for input / output command driven programming language. Usually connected to the card, select the base address. This allows a different card or card number the same host in the same PC connection and operation. The second method is to use the interface circuit board with a digital voltage meter and frequency meter and other equipment to control the PC, to receive data. The Common Criteria is an international Association of Electrical and Electronics Engineers IEEE-488 standard parallel communication link. Comparison of fast, easy and economical is the first approach, using the input / output port address the card to the PC, the output of the measurement data or control signals received from the PC machine. These cards are versatile, easy to obtain, and has the following characteristics:(1) multi-channel digital input / Shucu interface with optical isolation and Darlington driver settings.(2) pulse timing and counting facilities.(3) multi-channel programmable A / D conversion.(4) D / A conversion.(5) thermocouple input.PC machine control applications including the latest developments in data acquisition and control software, can provide the user with a drop-down menus and mouse-driven windows environment.Before the invention of the computer control system main relay logic circuit with electrical or pneumatic logic circuits to automate. The late 20th century invention of 60 programmable logic controllers (PLC) directly instead of the relay controller. It should be noted, in the United States, also known as programmable logic controller PLC, abbreviated as PC. Do it with a personal computer PC or IBM-PC to be confused.Programmable logic controllers and micro-computer composed of the same, there are microprocessors, memory and input / output devices. Processor performs memory control process according to input instructions, defined by the logic control program to provide output. Every step during the implementation period, the program is quickly scanned to record all of the input state, then the program logic to determine output. Controller scan each of these steps are repeated.Some small, dedicated to the sequential control of the programmable logic controller usually has 12 input ports and eight output ports are extended to both pinch the 128 input / output circuit. Input interface connected to these lines, the process of receiving input signals from the control, and these signals into a form suitable for processing. Similarly, the programmable logic controller output interface with a variety of process hardware, such as lights, motors, relays and spiral coil.Using a handheld programming keyboard, or with the corresponding software development kit with a personal computer connected to the programmable controller command input random access memory, the random access memory with battery backup power supply generally. If the programmer to establish procedures for using the symbol key, and some programming console LCD display can also display some of the graphics, using ladder logic diagram shows the format process. After a debugging program, the control method through simulation testing, you can put code into erasable programmable read-only memory chips, mounted on the programmable logic controller.Many manufacturers are in the manufacture of programmable logic controller. Although some manufacturers use their own proprietary software language, but most are still using ladder logic diagrams. Invention of this language is intended to be more acceptable to some customers, these customers are interested in is how to shift from hard-line programmable logic controller, relay control. In addition to input / output devices, the programmable logic controller also includes timers, counters, and other special function devices.Communication with other control devices exchange the traditional programmable logic controller is not the strengths of the network. Many industrial controllers are equipped with RS232 serial port, and other digital control equipment systems to exchange information.The robotIndustrial robot is a tool to improve manufacturing productivity. He can assume that humans may have dangerous jobs. The first industrial robot in nuclear power plants had to be replaced and the fuel rods. Industrial robots can work on the assembly line, such as the installation of electronic components, printed circuitboard. In this way, people can escape the monotony of the work stand out. Robots can also remove the bomb, as the disabled person services for our community to do all kinds of work.Robot is a re-programming, multi-agency work can be pre-programmed positions in all moving parts, materials, tools or other special equipment, complete a variety of different jobs.The location is pre-programmed robot to complete the work must follow the path. In some pre-programmed location, the robot will stop some operations, such as installing parts, painting or welding. These pre-programmed location is stored in the robot's memory to recall at any time of continuous operation. If the job requirements changed, the location of these pre-programmed data, together with other programming can be changed. These characteristics make industrial robot programming and computer are very similar.Robot system can control the robot's work unit. Robot work cell robots perform tasks in the work environment. Unit of work, including the robot manipulator, controller, working platforms, safety equipment and gear. In addition, the robot should be able to communicate with the outside world signals.Robot manipulator to complete the specific work of the robot system, which consists of two parts: the mechanical parts and ancillary parts. Subsidiary part of the installed robot base. Several fixed on the floor at the job site. But sometimes the base is able to move, in this case, the base placed in orbit for the robot from one location to another location should be.Subsidiary part of the robot arm. It may be a straight arm can move, it may be a hinged arm, the robot work to provide multiple axes. Articulated arm that is connected to the relevant section of the arm. End of the arm with a wrist. Wrist mounted on another shaft and fitted with flange root. In the flange also can be connected to different tools to complete different tasks. Mechanical axis allows the robot hand in a specific area to work. This area is called the robot unit of work, it depends on the size of the robot. If the robot the size of the increase will increase the size of the unit of work.Manipulator movement control drive or drive system. They drive the state work unit in the rotation. Drive system can make the electrical, hydraulic, it can be pneumatic. Drive power generated by the various institutions converted intomechanical energy, all kinds of drive system is connected by mechanical transmission. Those from the chain, gears and ball screw driven mechanical transmission device composed of the axis of the robot.Used to control the robot to control its movement and the work unit of the external device. Handheld keyboard by hanging the movement of the robot controller program input. The data stored in the controller's memory for future calls.Controllers also work in the unit with an external device to communicate. For example, the controller has an input line. Completion of processing input lines connected, high-speed controller for robot pick in the specified location processed parts. Mechanical hand a new part into the machine, the controller send a signal to start processing.Some of the drum controller is composed by a mechanical operation, the internal implementation of the input sequence of events. The controller is generally used very simple robot system. Most of the robot controller in your system much more complex, reflecting the latest developments in electronic technology. They are controlled by the microprocessor, the operation more flexible.The controller can transmit signals in the communications line. This mechanical hand and two-way communication between the controllers continuously update the location and operation of the system. The controller also includes a computer with different devices to communicate. This communication link to the robot as part of computer-aided manufacturing systems. Microprocessor system uses solid-state storage devices. These storage devices may be magnetic guns, random access memory, floppy disks and tapes.Controller and the robot powered by a power source supply. Robotic systems typically use two kinds of power: a controller may provide alternating current; the other power source used to drive each axis manipulator. For example, if the robot is controlled by a hydraulic or pneumatic drive, these devices will receive the control signal, a robot in motion.The robot sensorAlthough the robot has great ability, but often than not with a little practice, but the workers. For example, workers can find parts that fell on the ground or no parts feeder. But not the sensor, the robot will not get this information. Even the mostsophisticated sensor system, the robot is smaller than an experienced worker. Therefore, a good robot system design requires many sensor and robot controller using the phase to make it operate as close as possible the perception of workers. The most frequently used robotics sensors into contact with the non-contact. Contact sensors can be further divided into tactile sensors, force and torque sensors. Tactile or contact sensors can be measured by the drive-side and the actual contact between other objects, micro-switch is a simple tactile sensor. When the robot by the drive-side contact with other objects, the robot stop motion sensors to avoid collisions between objects to tell the robot has reached the goal; or detection to measure the size of the object. Force and torque sensors in the robot's gripper and wrist joint between the last, or the load on the robot parts, measuring reaction force and torque. Force and torque sensors and piezoelectric sensors are mounted on flexible parts of the strain gauges.Non-contact sensors include proximity sensors, vision sensors, sound detectors, sensitive components and scope. Proximity sensors detect objects near the sensor and the label. For example, eddy current sensor can accurately maintain a fixed distance between the plates. Most cheap robot proximity sensors including a light-emitting diode and a photodiode receiver transmitter, receiver reflector closer to the reflection of light. The main disadvantage of this sensor is closer to the object reflectance of light will affect the received signal. Other proximity sensors using capacitance and inductance associated with the principle.Visual sensing system is very complex, based on the TV camera or laser scanner works. Video signal by hardware pretreatment to 30-60 per second input into the computer. Computer analysis of the data and extract the required information, such as the existence of objects and object features, location, direction of operation, or assembly of components and product testing is complete.Sound sensitive devices used to sense and interpret sound waves. To detect sound waves from the basic continuous speech word for word recognition that people, all kinds of sound ranging from the complexity of sensitive components. In addition to human verbal communication, the robot can use voice control of sensitive components arc welding, I heard the voice of the collision or the collapse of the movement of the robot when the organization to predict the mechanical damage will occur and the detection of objects within the defects.There is also a non-contact systems for projector and imaging the surface of the object surface shape information or distance information.Static detection and closed-loop sensor probe used in two ways. When the detection and operation of the robot system moves alternately, it is usually necessary to use the sensor. That probe is a robot is not operating, the operation has nothing to do with the sensors, this method is called static detection. In this way, vision sensors are looking for is to capture the position and direction of the object, then the robot moves straight to the site.In contrast, closed-loop operation of motion detection robot, always under the control of the sensor. Most sensors are closed loop mode, they can always detect the actual location of the robot and the deviation between the ideal position, and drive the robot fix this error. In the closed-loop detection, even if the object in motion, for example, the conveyor belt, the robot can grasp it and sent it to the desired location.However, in the early 20th century, 80, a number of factors hindered the development of closed-loop detection. The most important reason is the image map for too long, almost equal to the robot move from one place to another time. For practical, for the robot arm motion, image analysis time by reducing down time should be able to accept and explain a few frames.In the use of force and tactile sensor control movement, reaction time to visual sensor that is no longer a problem, because very little information when the sensor transmission. In other words, we can placed on the wrist force and torque sensor 6, or place a finger on the low-resolution binary sensor array. Since the sensor more complex, we can expect delivery by the sensor data can be more of information.中文翻译:工业机器人机电一体化在国际市场中,制造业和工业产品德销售业绩取得的成绩,越来越依靠电子技术和计算机技术与传统机械制造和机械产品的广泛结合。
智能防疫机器人英语作文
智能防疫机器人英语作文Title: The Role of Intelligent Epidemic Prevention Robots。
In the face of global health crises like pandemics, the integration of technology into epidemic prevention measures has become increasingly essential. One such innovative solution is the deployment of intelligent epidemic prevention robots. These robots, equipped with advanced technologies, play a crucial role in containing the spread of diseases and ensuring public health and safety.First and foremost, intelligent epidemic prevention robots are equipped with various sensors and detectors that enable them to detect potential threats efficiently. For instance, they can detect body temperature, monitor air quality, and identify individuals not wearing masks in public areas. By continuously scanning their surroundings, these robots provide real-time data to authorities, allowing for prompt responses to any emerging risks.Moreover, these robots are designed to perform tasks that minimize human-to-human contact, thereby reducing the risk of transmission. They can be deployed in various settings, such as hospitals, airports, and shopping malls, to perform tasks like disinfection, package delivery, and even providing basic medical assistance. Their ability to autonomously navigate through spaces and execute predefined tasks significantly reduces the workload of human personnel while ensuring the continuity of essential services.Furthermore, intelligent epidemic prevention robots serve as effective communication tools to disseminate vital information to the public. Through built-in speakers and screens, they can broadcast public health announcements, guidelines, and emergency alerts in multiple languages. This capability helps in raising awareness, educating the public about preventive measures, and dispelling misinformation, thus fostering a sense of collective responsibility in combating the spread of diseases.Additionally, these robots contribute to datacollection and analysis, which is crucial for epidemiological research and policymaking. By collecting data on human movement patterns, crowd density, and compliance with preventive measures, they provide valuable insights that help authorities better understand the dynamics of disease transmission and formulate targeted intervention strategies. Moreover, the integration of artificial intelligence allows these robots to continuously learn and improve their performance over time, making them more effective in mitigating future health crises.Despite their numerous benefits, intelligent epidemic prevention robots also pose certain challenges and ethical considerations. Concerns regarding privacy invasion, job displacement, and reliance on technology are often raised. Therefore, it is imperative to establish clear guidelines and regulations governing the use of these robots to address these concerns and ensure their responsible deployment.In conclusion, intelligent epidemic prevention robots represent a promising solution in the fight againstpandemics and other health emergencies. Their ability to detect threats, perform tasks autonomously, communicate with the public, and contribute to data collection makes them invaluable assets in safeguarding public health and mitigating the impact of infectious diseases. However, their deployment should be accompanied by careful consideration of ethical and societal implications to maximize their benefits while minimizing potential risks. Through collaboration between technology developers, policymakers, and healthcare professionals, we can harness the full potential of these robots to create a safer and healthier future for all.。
设计机器人 英语作文
设计机器人英语作文Designing a Robot。
As technology continues to advance, designing robotshas become an exciting and innovative field. Robots are machines that are programmed to perform specific tasks,often with greater efficiency and precision than humans. In this essay, I will discuss the process of designing a robot, including the different types of robots and their applications, the components that make up a robot, and the challenges that designers face.Types of Robots and Their Applications。
There are several types of robots, each designed for a specific task. Industrial robots are used in manufacturing plants to perform tasks such as welding, painting, and assembly. Medical robots are used in hospitals to perform surgeries and other medical procedures. Service robots are used in homes and businesses to perform tasks such ascleaning and security. Military robots are used by the military for reconnaissance and combat.Components of a Robot。
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INTELLIGENT VEHICLEOur society is awash in “machine intelligence” of various kinds.Over the last century, we have witnessed more and more of the “drudgery” of daily living being replaced by devices such as washing machines.One remaining area of both drudgery and danger, however, is the daily act ofdriving automobiles 1.2 million people were killed in traffic crashes in 2002, which was 2.1% of all globaldeaths and the 11th ranked cause of death . If this trend continues, an estimated 8.5 million people will be dying every year in road crashes by 2020. In fact, the U.S. Department of Transportation has estimated the overall societal cost of road crashes annually in the United States at greater than $230 billion.When hundreds or thousands of vehicles are sharing the same roads at the same time, leading to the all too familiar experience of congested traffic. Traffic congestion undermines our quality of life in the same way air pollution undermines public health.Around 1990, road transportation professionals began to apply them to traffic and road management. Thus was born the intelligent transportation system(ITS). Starting in the late 1990s, ITS systems were developed and deployed. In developed countries, travelers today have access to signifi-cant amounts of information about travel conditions, whether they are driving their own vehicle or riding on public transit systems.As the world energy crisis, and the war and the energyconsumption of oil -- and are full of energy, in one day, someday it will disappear without a trace. Oil is not in resources. So in oil consumption must be clean before finding a replacement. With the development of science and technology the progress of the society, people invented the electric car. Electric cars will become the most ideal of transportation.In the development of world each aspect is fruitful, especially with the automobile electronic technology and computer and rapid development of the information age. The electronic control technology in the car on a wide range of applications, the application of the electronic device, cars, and electronic technology not only to improve and enhance the quality and the traditional automobile electrical performance, but also improve the automobile fuel economy, performance, reliability and emissions purification. Widely used in automobile electronic products not only reduces the cost and reduce the complexity of the maintenance. From the fuel injection engine ignition devices, air control and emission control and fault diagnosis to the body auxiliary devices are generally used in electronic control technology, auto development mainly electromechanical integration. Widely used in automotive electronic control ignition system mainly electronic control fuel injection system, electronic control ignition system, electronic control automatic transmission,electronic control (ABS/ASR) control system, electronic control suspension system, electronic control power steering system, vehicle dynamic control system, the airbag systems, active belt system, electronic control system and the automatic air-conditioning and GPS navigation system etc. With the system response, the use function of quick car, high reliability, guarantees of engine power and reduce fuel consumption and emission regulations meet standards.The car is essential to modern traffic tools. And electric cars bring us infinite joy will give us the physical and mental relaxation. Take for example, automatic transmission in road, can not on the clutch, can achieve automatic shift and engine flameout, not so effective improve the driving convenience lighten the fatigue strength. Automatic transmission consists mainly of hydraulic torque converter, gear transmission, pump, hydraulic control system, electronic control system and oil cooling system, etc. The electronic control of suspension is mainly used to cushion the impact of the body and the road to reduce vibration that car getting smooth-going and stability. When the vehicle in the car when the road uneven road can according to automatically adjust the height. When the car ratio of height, low set to gas or oil cylinder filling or oil. If is opposite, gas or diarrhea. To ensure and improve the level of driving cars driving stability. Variable force power steering system can significantly change the driver for the workefficiency and the state, so widely usedin electric cars. VDC to vehicle performance has important function it can according to the need of active braking to change the wheels of the car, car motions of state and optimum control performance, and increased automobile adhesion, controlling and stability. Besides these, appear beyond 4WS 4WD electric cars can greatly improve the performance of the value and ascending simultaneously. ABS braking distance is reduced and can keep turning skills effectively improve the stability of the directions simultaneously reduce tyre wear. The airbag appear in large programs protected the driver and passenger's safety, and greatly reduce automobile in collision of drivers and passengers in the buffer, to protect the safety of life.Intelligent electronic technology in the bus to promote safe driving and that the other functions. The realization of automatic driving through various sensors. Except some smart cars equipped with multiple outside sensors can fully perception of information and traffic facilities and to judge whether the vehicles and drivers in danger, has the independent pathfinding, navigation, avoid bump, no parking fees etc. Function. Effectively improve the safe transport of manipulation, reduce the pilot fatigue, improve passenger comfort. Of course battery electric vehicle is the key, the electric car battery mainly has: the use of lead-acidbatteries, nickel cadmium battery, the battery, sodium sulfide sodium sulfide lithium battery, the battery, the battery, the flywheel zinc - air fuel cell and solar battery, the battery. In many kind of cells, the fuel cell is by far the most want to solve the problem of energy shortage car. Fuel cells have high pollution characteristics, different from other battery, the battery, need not only external constantly supply of fuel and electricity can continuously steadily. Fuel cell vehicles (FCEV) can be matched with the car engine performance and fuel economy and emission in the aspects of superior internal-combustion vehicles.Along with the computer and electronic product constantly upgrading electric car, open class in mature technology and perfected, that drive more safe, convenient and flexible, comfortable. Electric cars with traditional to compete in the market, the car will was electric cars and intelligent car replaced. This is the question that day after timing will come. ABS, GPS, and various new 4WD 4WS, electronic products and the modern era, excellent performance auto tacit understanding is tie-in, bring us unparalleled precision driving comfort and safety of driving.The hardware and software of the intelligent vehicle are designed based on AVR.This system could set the route in advance. The vehicle could communicate with the PC vianRF401 and could run safely withthe help of ultra sound detection and infrared measuring circuit. Neural network self- study is used to improve the intelligence of the vehicle.The performance of servo systems will determine the property of the robot. Based on AVRseries MCU,the velocity servo system for driving motor is created in this paper,including a discrete PIregulator which will work out a PWM control signal with applying the skill of integral separation.The velocities of motors will be controlled real-time with the speed sampling frequency set for 2KHz by using the AVR-GCC compiler software pared to the servo system development based on the 51 Series MCU,the system here has these advantages of simpler peripheral circuit and faster data processing.The experiments demonstrate that,the mobile robot runs stably and smoothly by the control of AVR units,and that the design proposal especially benefits the development of intelligent mobile robots,also can be widely used in the development of other smart devices and product lines.A new design of contest robot control system based on AVR Atmega8 was put forward. According to the character of contest robot , the main control unit , motor drive unit , sense detection unit and LCD display unit were introduced. Furthermore the servo driver system based on MCBL3006S , the line t racker sensor system and the obstacle avoidance sensor system were presented in detail.Finally theperformance shows that the control system is open,simple,easy programming,intelligent and efficiency.Avoidance rules of intelligent vehicle obstacle are intro ducted.Through the collection of infrared sensor formation,the rules use diode D1 to launch and diode D2 to receive infrared signals. Infrared transmitter signal without a dedicated circuitcomes directly from the MCU clock frequency, which not only simplifier the circuit and debugging, but also make the circuit stability and anti- jamming capability greatly enhanced.After the experimental verification,the system runs reliably meet the design requirements.A smart car control system of the path information identified based on CCD camera was introduced.The hardware structure and scheme were designed. The control strategy of s teering mechanism was presented. The smart car not only can identify the road precisely, but also have ant-interference performance, and small steady state error.This article designed smart car system,includes the aspects of the sensor information acquisition and processing, motor drive, control algorithm and control strategy ing laser sensor to collect the road information which can feedback to the micro-controller control system,then making analytical processing combined with the software.With velocity feedback and PID control algorithms to control steering engine and the speed of smart car.Verified by actualoperation, this method makes smart car travel stably and reliably,and its average speed to reach 2.6m /s, and get a satisfied results.By the aid of the professional know ledge of control, patter n recognition, sensor technology, aut omotive electronics, electricity, computer, machinery and so on, an intelligent vehicle system is designed with PID control algorithm,CCD detection system and HC9SDG128 MCU. Code Warrior IDE integrated development programming environment is taken as a basic softy are platform that can automatically deal with the traffic and image pro cessing, and then adjust the moving direction along the scheduled or bit by t he aid of a CCD camera. The system has many advantages, such as high reliability , high stability, good speed ability and scalability.Based on the research background of the Free-Scale smart car competition,a smart track following car is designed. In the car, the photo electricity sensor is used to check the path and obtain the information of racing road, and calculate the errorbetween the car and the black line. The fuzzy control is used to control the velocity of the car. The experiments show that the smart car based on the fuzzy control has high accuracy on the judgment of the path, stability and velocity control.智能车我们的社会充斥着各种各样的“机器智能“。