Master\u2019s Degree in Industrial Engineering \u2013 Two Year Duration
\nThe Master\u2019s Degree in Industrial Engineering prepares students to enter management and leadership roles in the field. In addition to qualifying for industrial engineer and industrial production manager positions in a variety of businesses, they may find themselves working as supply chain managers or health and safety managers. Concentration options in master\u2019s programs may include operations research, logistics and transportation systems, quality engineering and management, engineering management, and manufacturing systems.

\n

These are some common courses offered at this level:

\n\n

Doctoral Degree in Industrial Engineering \u2013 Five to Seven Year Duration
\nPh.D. programs in the field are focused on preparing students to present a thesis on an industrial engineering topic. Courses commonly cover:

\n", "display_order": 2, "created_at": "2019-08-29T17:56:39.291143-07:00", "updated_at": "2021-12-13T13:11:18.658871-08:00"}, {"degree_id": 90, "page": 1, "title": "Degrees Similar to Industrial Engineering", "summary_markdown": "**[Business Administration](/degrees/business-administration-degree/)** \r\nDegree programs in business administration teach students how to operate a business from the perspectives of marketing, accounting, human resources, and operations. Typical courses include operations management, financial management, management information systems, business ethics and law, human resources, and marketing.\r\n\r\n**[Management Information Systems](/degrees/management-information-systems-degree/) / [Systems Engineering](/degrees/systems-engineering-degree/)** \r\nThese degree programs are concerned with how to use math and science to develop innovative technologies that help run businesses. Students take courses in operations management, computer-based simulation systems, and statistical applications in business.\r\n\r\n**Engineering Technology** \r\nEngineering technology programs teach the engineering skills required to assist engineers in their work. Common classes are computers for engineering technology, construction methodologies, structural systems, strength of materials, and technical drawing.", "content_markdown": "**[Chemical Engineering](/degrees/chemical-engineering-degree/)** \r\nThis degree field is focused on how the chemical, biochemical, and physical properties of substances can be changed to turn them into something else. Examples of this work are making plastic from oil, developing synthetic fibers for clothing, identifying ways to mass-produce drugs, and finding ways to solve environmental problems.\r\n\r\n**[Robotics Technology](/degrees/robotics-technology-degree/)** \r\nAs its name implies, this field uses engineering principles to create and test robots to be used in various sectors. Coursework in the degree program covers robotics and robot design, testing, and repair.\r\n\r\n**[Mechanical Engineering](/degrees/mechanical-engineering-degree/)** \r\nStudents of mechanical engineering learn about the science behind machines. They study statics and dynamics, thermodynamics, fluid dynamics, stress analysis, mechanical design, and technical drawing.", "content_html": "

Chemical Engineering
\nThis degree field is focused on how the chemical, biochemical, and physical properties of substances can be changed to turn them into something else. Examples of this work are making plastic from oil, developing synthetic fibers for clothing, identifying ways to mass-produce drugs, and finding ways to solve environmental problems.

\n

Robotics Technology
\nAs its name implies, this field uses engineering principles to create and test robots to be used in various sectors. Coursework in the degree program covers robotics and robot design, testing, and repair.

\n

Mechanical Engineering
\nStudents of mechanical engineering learn about the science behind machines. They study statics and dynamics, thermodynamics, fluid dynamics, stress analysis, mechanical design, and technical drawing.

", "display_order": 3, "created_at": "2019-08-29T17:56:39.293299-07:00", "updated_at": "2021-12-13T13:05:53.811333-08:00"}, {"degree_id": 90, "page": 1, "title": "Skills You’ll Learn", "summary_markdown": "Industrial engineering students learn how to combine technical knowledge with business acumen. Upon completing their studies, therefore, they have developed several transferable skills:\r\n\r\n- Math and Quantitative Skills\r\n- Research\r\n- Data Analysis\r\n- Detailed Thinking / Creative Problem-Solving\r\n- Patience\r\n- Willingness to Learn\r\n- Passion for Improving Methods and Systems\r\n- Quality Control\r\n- Cost Control\r\n- Understanding of Processes\r\n- Facility Design\r\n- Understanding of Human Factors\r\n- Organizational Management", "content_markdown": "", "content_html": "

Industrial engineering students learn how to combine technical knowledge with business acumen. Upon completing their studies, therefore, they have developed several transferable skills:

\n", "display_order": 4, "created_at": "2019-08-29T17:56:39.295367-07:00", "updated_at": "2021-11-18T13:55:37.980468-08:00"}, {"degree_id": 90, "page": 1, "title": "What Can You Do with an Industrial Engineering Degree?", "summary_markdown": "To function at the highest level of productivity, companies in many industries employ [industrial engineers](/careers/industrial-engineer/) to improve processes, products, and systems.\r\n\r\nHere are some examples of those industries and sectors:\r\n\r\n- Aerospace and Aviation\r\n- Aluminum and Steel\r\n- Banking\r\n- Construction\r\n- Consulting\r\n- Electronics Assembly\r\n- Energy\r\n- Entertainment\r\n- Forestry and Logging\r\n- Government Agencies\r\n- Insurance\r\n- Materials Testing\r\n- Medical Services\r\n- Military\r\n- Mining\r\n- Oil and Gas\r\n- Plastics and Forming\r\n- Retail\r\n- Shipbuilding\r\n- Transportation", "content_markdown": "Within any of these sectors, industrial engineers may be employed or contracted to manage a variety of tasks. Listed for each kind of work below is an example of a potential assignment.\r\n\r\n**Project Management** \r\nConduct facility planning; revise designs of production plants and office buildings\r\n\r\n**Manufacturing, Production, and Distribution** \r\nCreate instructions and documentation to optimize production and distribution\r\n\r\n**Supply Chain Management** \r\nManage supplier relationships\r\n\r\n**Productivity, Methods, and Process Engineering** \r\nIdentify efficient processes for work flow\r\n\r\n**Quality Measurement and Improvement** \r\nWork with design and production teams to maintain / improve product quality\r\n\r\n**Program Management** \r\nManage program schedule, budget, and performance expectations\r\n\r\n**Ergonomics / Human Factors** \r\nDefine ergonomics policies to minimize causes of employee injury and discomfort\r\n\r\n**Technology Development and Transfer** \r\nDetermine if a technology- or a process-based solution is best\r\n\r\n**Strategic Planning** \r\nDevelop long-range planning models, often five to ten years in scope\r\n\r\n**Change Management** \r\nCoordinate change programs and ensure that everyone involved understands and supports the change\r\n\r\n**Financial Engineering** \r\nPerform *make* versus *buy* versus *lease* analyses", "content_html": "

Within any of these sectors, industrial engineers may be employed or contracted to manage a variety of tasks. Listed for each kind of work below is an example of a potential assignment.

\n

Project Management
\nConduct facility planning; revise designs of production plants and office buildings

\n

Manufacturing, Production, and Distribution
\nCreate instructions and documentation to optimize production and distribution

\n

Supply Chain Management
\nManage supplier relationships

\n

Productivity, Methods, and Process Engineering
\nIdentify efficient processes for work flow

\n

Quality Measurement and Improvement
\nWork with design and production teams to maintain / improve product quality

\n

Program Management
\nManage program schedule, budget, and performance expectations

\n

Ergonomics / Human Factors
\nDefine ergonomics policies to minimize causes of employee injury and discomfort

\n

Technology Development and Transfer
\nDetermine if a technology- or a process-based solution is best

\n

Strategic Planning
\nDevelop long-range planning models, often five to ten years in scope

\n

Change Management
\nCoordinate change programs and ensure that everyone involved understands and supports the change

\n

Financial Engineering
\nPerform make versus buy versus lease analyses

", "display_order": 5, "created_at": "2019-08-29T17:56:39.297549-07:00", "updated_at": "2021-12-13T13:07:00.066043-08:00"}], "degree_specializations": []}">

什么是工业工程学位?

工业工程是关于整合工人、机器、材料、信息和能源,以消除生产过程中的危险和浪费。因此,该领域的学位课程的目标是教授有抱负的人工业工程师如何设计系统,使企业能够提高工作场所的安全、生产力、效率和质量。

工业工程的基础课程包括微积分、工程师统计学、设施规划和物流、项目管理、计算机编程、库存控制和工程中的人为因素等科目。更高级的主题包括制造和仓储系统,生产力测量,供应链系统,计算统计和融资。

程序选项

工业工程副学士学位-两年制
在这个层次,有两个学位选择,都需要两年的学习:工业工程技术应用科学副学士学位和工业制造副学士学位。典型的课程包括数学、自然科学和社会科学。针对工程领域的课程包括以下内容:

  • 生产管理
  • 工业计算机化
  • 质量控制
  • 计算机辅助设计(CAD)
  • 技术视觉和图纸
  • 商业基础

工业工程学士学位-四年
在大多数情况下,学士学位是工程领域工作的最低学位要求。在这个层次的教育中,学生可以选择一个专业。其中包括一般工业和系统工程,供应链物流,制造系统和经济学。常见课程包括:

  • 计算机软件设计
  • 概率评估
  • 数学建模
  • 项目管理
  • 库存管理
  • 优化(实现设计目标)

工业工程硕士学位-两年制
工业工程硕士学位培养学生进入该领域的管理和领导角色。除了有资格担任各种行业的工业工程师和工业生产经理职位外,他们还可能会成为供应链经理或健康和安全经理。硕士课程的集中选项可能包括运筹学、物流和运输系统、质量工程和管理、工程管理和制造系统。

以下是这个级别的一些常见课程:

  • 假设检验
  • 数据建模
  • 控制理论
  • 质量控制与改进
  • 设施规划及设计
  • 多级制造
  • 运输和供应链系统
  • 仓储系统

工业工程博士学位,5 - 7年
该领域的博士课程的重点是准备学生提出一个工业工程主题的论文。课程一般包括:

  • 工程理论
  • 研究方法
  • 方差分析-预算与实际绩效之间的差异
  • 系统设计
  • 高级工程统计学
  • 信息系统
  • 工业工程管理

与工业工程类似的学位

工商管理
工商管理学位课程教学生如何从市场营销、会计、人力资源和运营的角度经营企业。典型课程包括运营管理、财务管理、管理信息系统、商业道德与法律、人力资源和市场营销。

管理信息系统/系统工程
这些学位课程关注的是如何利用数学和科学来开发有助于经营企业的创新技术。学生学习运营管理、基于计算机的模拟系统和商业统计应用等课程。

工程技术
工程技术专业教授协助工程师工作所需的工程技能。常见的课程有工程技术计算机、施工方法、结构系统、材料强度和技术绘图。

化学工程
该学位领域主要研究如何改变物质的化学、生物化学和物理性质,从而将其转变为其他物质。这方面的工作包括从石油中制造塑料,开发用于服装的合成纤维,确定大规模生产药物的方法,以及寻找解决环境问题的方法。

机器人技术
顾名思义,这个领域使用工程学原理来创建和测试用于各个领域的机器人。学位课程包括机器人和机器人设计、测试和维修。

机械工程
机械工程专业的学生学习机器背后的科学。他们学习静力学和动力学、热力学、流体动力学、应力分析、机械设计和技术绘图。

你将学会的技能

工业工程专业的学生学习如何将技术知识与商业头脑结合起来。因此,在完成学业后,他们已经开发了几种可转移的技能:

  • 数学和定量技能
  • 研究
  • 数据分析
  • 详细思考/创造性解决问题
  • 耐心
  • 学习的意愿
  • 热衷于改进方法和系统
  • 质量控制
  • 成本控制
  • 对流程的理解
  • 设施设计
  • 对人为因素的理解
  • 组织管理

工业工程学位能做什么?

为了在最高的生产力水平上运作,许多行业的公司雇佣工业工程师改进流程、产品和系统。

以下是这些行业和部门的一些例子:

  • 航空航天
  • 铝和钢铁
  • 银行
  • 建设
  • 咨询
  • 电子产品组装
  • 能源
  • 娱乐
  • 林业和伐木业
  • 政府机构
  • 保险
  • 材料测试
  • 医疗服务
  • 军事
  • 矿业
  • 石油和天然气
  • 塑料及成型
  • 零售
  • 造船
  • 运输

在这些部门中,工业工程师可以受雇或承包管理各种任务。下面列出的每一种工作都是一个潜在任务的例子。

项目管理
进行设施规划;修改生产厂房和办公楼的设计

制造、生产和分销
创建指令和文件,以优化生产和分销

供应链管理
管理供应商关系

生产力、方法和过程工程
确定工作流程的有效流程

质量测量与改进
与设计和生产团队合作,保持/提高产品质量

项目管理
管理项目进度、预算和绩效预期

人体工程学/人为因素
定义人体工程学政策,尽量减少员工受伤和不适的原因

技术开发和转让
确定基于技术还是基于流程的解决方案是最好的

战略规划
制定长期规划模型,通常为5到10年的范围

变更管理
协调变革计划,确保参与变革的每个人都理解并支持变革

金融工程
执行使租赁分析

学费

看看哪些学校学费最贵,哪些学校学费最便宜。

了解学费