Table of Contents:

1. AI is here to assist you 

• Drafting and Documentation
• AI Role in Simulation Setup
• Standardisation and Compliance Checks
• Bill of Materials (BOM) Generation

2. Integrating IoT in Engineering Design

• Smart Sensing and Data Collection
• Predictive Maintenance
• Performance Optimization

3. Revit and AI-powered Design:

• Automated Parametric Design
• Energy Analysis and Optimization
• Enhanced Collaboration

4. AI is here to inspire you 

• Guided design
• Generative design
• Iterative design

Artificial Intelligence(AI) elicits a mixed reaction among engineering design professionals as it does among the knowledge workers of other fields where it has made inroads.

While this disruptive technology has made significant progress and brought numerous benefits to engineering design, there are also concerns, challenges, and differing opinions surrounding AI’s implementation and implications.

At CADD Centre, we believe that AI can serve as both your assistant and master. It acts as an assistant by handling repetitive design tasks with precision and accuracy, reducing errors and saving you valuable time.

Simultaneously, it acts as a master by generating inspiring designs that expand your horizons and teach you what is achievable in your field of expertise.

AI is here to assist you 

In engineering design, there are several repetitive tasks that can benefit from automation through AI. Some examples of such tasks include:

Drafting and Documentation:

Creating detailed engineering drawings, including dimensioning, annotation, and documentation, can be time-consuming and repetitive.

AI can assist you in automating the generation of standardized drawings, reducing the manual effort required. 

The technology can explore design spaces that are difficult and time-consuming for you to do so manually.

For instance, it can consider a large number of variables, complex geometries, and intricate relationships between design parameters, and suggest options.

AI Role in Simulation Setup:

Preparing and setting up simulations for various engineering analyses, such as structural analysis, fluid dynamics, or thermal simulations, can involve repetitive steps.

AI can automate simulation setup processes, including meshing, boundary condition assignment, and material property input.

It can help you predict the behavior of complex systems, analyze structural integrity, fluid dynamics, thermal properties, and more. 

Standardisation and Compliance Checks:

Ensuring compliance with design standards, regulations, and industry-specific requirements often involves repetitive checks.

AI can assist in automating these checks, verifying design compliance, and flagging potential deviations or non-compliant elements.

It can verify design integrity, such as checking for interference, clash detection, or assembly constraints. 

Bill of Materials (BOM) Generation:

Compiling accurate and detailed BOMs for complex products or systems can be a repetitive task.

AI can help you automate the generation of BOMs by analyzing the design and extracting relevant information from the 3D model or design documentation.

By automating these repetitive design tasks, you can focus more on higher-level activities such as conceptualization, innovation, and critical decision-making, and increase your productivity and efficiency in your career.

Integrating IoT in Engineering Design:

Incorporating the Internet of Things (IoT) concept into engineering design can revolutionize the way products and systems are conceived, developed, and operated.

IoT refers to the network of interconnected devices and sensors that collect and exchange data, enabling real-time monitoring, control, and analysis.

Here’s how AI and IoT can work together in engineering design:

• Smart Sensing and Data Collection:

  • IoT devices and sensors can be embedded in products and structures to collect data on their performance, usage, and environmental conditions.
  • AI can then process this data, providing valuable insights into the behavior and health of the designed systems.
  • This real-time feedback loop can lead to more informed design decisions and proactive maintenance strategies.

• Predictive Maintenance:

  • AI can analyze data from IoT-enabled devices to predict when maintenance is required or when components are likely to fail.
  • By integrating these insights into the design process, engineers can create more reliable and durable products, minimizing downtime and maintenance costs.

• Performance Optimization:

  • IoT data can be used to monitor the performance of products and systems in real-world conditions.
  • AI can analyze this data to identify areas for improvement, enabling engineers to optimize the design and enhance efficiency, safety, and functionality.

Revit and AI-powered Design:

Revit, a Building Information Modeling (BIM) software developed by Autodesk, has become an essential tool in the architecture, engineering, and construction industries.

When combined with AI-powered design capabilities, Revit becomes even more powerful and versatile:

• Automated Parametric Design:

  • Revit, with AI integration, can generate parametric designs based on specific input parameters and constraints.
  • The software can automatically create and modify design iterations, allowing engineers to explore various possibilities and optimize their designs efficiently.

• Energy Analysis and Optimization:

  • By leveraging AI algorithms, Revit can perform energy analysis and optimization on building designs.
  • It can suggest energy-efficient solutions and help engineers meet sustainability and regulatory requirements.

• Enhanced Collaboration:

  • IoT devices and sensors can be incorporated into building designs through Revit’s BIM capabilities.
  • This integration allows for better collaboration between architects, engineers, and other stakeholders throughout the design, construction, and operation phases of a building.

AI is here to inspire you 

AI’s generative design is a cutting-edge approach to engineering design that enables you to explore a vast design space and generate optimized solutions.

You can move beyond traditional design methods, leveraging computational power and machine learning techniques, and discover innovative and efficient designs.

Some of the ways AI can “wow” you are:

• Guided design:

  • AI can also guide you in the design process, offering recommendations, providing design rules, and assisting in decision-making – all based on documented engineering knowledge and best practices. 

• Generative design:

  • AI can generate multiple designs based on your design requirements and the constraints you define, such as structural integrity, material properties, manufacturing limitations, and cost considerations.
  • You can define multiple criteria, such as weight reduction, structural strength, material usage, cost minimization, or performance improvement.
  • The algorithm then generates designs that strike a balance between these competing objectives, creating trade-off solutions effectively. 

• Iterative design:

  • AI uses computational techniques, such as evolutionary algorithms, genetic algorithms, or machine learning, to generate designs.
  • However, these designs serve only as starting points for further refinement and customization.
  • You can review the generated design alternatives and select those that best meet the desired objectives and constraints.
  • You can also let the technology iteratively modify and optimize the chosen designs based on your expertise, your feedback, and additional constraints.

Generative design can provide you with fresh design perspectives and inspire innovative solutions.

By exploring unconventional design options, AI challenges traditional design approaches and pushes the boundaries of what is considered feasible or optimal.

This can lead to breakthrough designs that are more efficient, lightweight, structurally sound, and visually striking.

To sum up, AI and IoT are not meant to replace engineering design professionals but rather to augment their creativity and expertise.

You will continue to play a critical role in setting design objectives, evaluating design iterations, interpreting results, and incorporating domain knowledge into the process.

The collaboration between AI, IoT, and human experts can lead to synergistic outcomes, combining the power of computational analysis and human ingenuity.

Hence, AI and IoT are here to relieve you of digital drudgery and to inspire you to be more creative.

What more can you ask for?

The post AI in Engineering Design: Get Help and Stay Inspired first appeared on CADD Centre Resource.

Discover the Latest Advancements and Opportunities in SolidWorks Designing

Do you want to improve your SolidWorks skills as a student or a working person? Would you like to learn more about the most recent developments in SolidWorks design? This blog post is for you if the answer is yes. In this post, we’ll talk about SolidWorks’ cutting-edge design options and how you may use them to your advantage.

Why Solidworks?

Engineers and designers frequently utilize SolidWorks, a popular computer-aided design (CAD) program, to build 3D models and simulations. It is extensively employed in sectors like consumer goods, medical gadgets, aircraft, and transportation. A variety of tools and capabilities provided by SolidWorks enable designers to quickly produce intricate models. SolidWorks has something to offer everyone, whether you are a novice or an expert user. It’s time to refresh your design knowledge on Solidworks 2022 since the Solidworks 2023 update is only a few months away.

New Features in SolidWorks

In order to stay on top of the most recent market trends, SolidWorks continually upgrades its software with new features and capabilities. SolidWorks 2022, the most recent edition, contains a number of new features, including:

Improved Simulation Capabilities:

Better simulation capabilities enable designers to correctly predict the behavior of their systems by simulating complicated scenarios.

Assembly Structure System:

SolidWorks 2020 marked the official release of the Assembly Structure System. Designers may arrange intricate assemblies in a more effective and logical manner thanks to this functionality. You may use this functionality to organize similar parts and subassemblies into folders and subfolders. An structured assembly system reduces mistakes and saves time by making it simpler to traverse and handle complicated assemblies.

Simplified User Interface:

SolidWorks is now accessible with a simplified user interface, making it simpler for users to explore the program and quickly discover the capabilities you want.

Mesh Modeling:

This feature makes it simpler to design intricate organic structures. Using this tool, you may manipulate the mesh geometry to produce intricate forms. This is especially helpful in sectors like automotive and consumer goods, where you need distinctive geometric designs.

Topology Study:

Another interesting feature that’s fairly new is Topology Study. With this, designs for weight and strength may be made. You may model the stresses and strains placed on their designs to find potential areas for weight-reduction optimization. This is especially helpful in sectors like aerospace and automotive, where reducing weight is essential for increasing productivity and efficiency.

Let’s examine the innovative designs we can produce with these newest SolidWorks capabilities in more detail, as well as how a properly-designed curriculum may aid in your development of these abilities to the fullest. 

Innovative Design Possibilities with SolidWorks

When it comes to innovative design concepts, SolidWorks provides countless alternatives. SolidWorks’ variety of tools and capabilities make it simple to produce intricate and detailed models fast and effectively. Innovative design options using SolidWorks include the following:

Design optimization:

SolidWorks provides simulation tools that enable designers to enhance the performance and effectiveness of their designs. Design optimization aids in the production of goods that are both economical and up to consumer standards.

Advanced Surfacing:

It provides powerful surfacing capabilities that enable designers to produce intricate, organic structures. In sectors like automotive and consumer goods, where items must have appealing looks, this trait is helpful.

Additive Manufacturing:

SolidWorks provides tools that enable designers to produce models for additive manufacturing. By adding layers of material rather than removing them, objects are made using the additive manufacturing technique. It is frequently utilized in fields like aerospace and medical equipment, which need complicated geometry.

Collaboration:

While utilizing SolidWorks, you may easily collaborate with your design team. The project may be easily collaborated on in real-time thanks to cloud-based design sharing. This feature enables increased designer cooperation, which improves design outputs. They may pool their knowledge and experience in real time by working together on the cloud-based system, leading to better designs and more creative solutions.

If you want to improve your SolidWorks designing skills, you can enroll in our SolidWorks certification course. This course is designed for both beginners and experienced users and covers topics such as 3D modeling, simulation, rendering, and assembly design. The course is available online and in person, and offers hands-on experience with the software.

Wrapping Up!

In today’s fast and competitive world, innovative design is crucial. Designers may push their limits and consider novel options with SolidWorks. SolidWorks provides a variety of tools and capabilities that may assist designers in achieving their creative design goals, from design optimization to advanced surfacing and additive manufacturing. 

SolidWorks is a powerful CAD program that provides countless options for creative design. SolidWorks gives designers the tools and functionality they need to quickly produce intricate models. Your professional abilities can be enhanced by obtaining a SolidWorks certification and registering for Advanced SolidWorks Training. Additionally, it makes you more marketable as a designer with in-depth knowledge of the program. 

The post SolidWorks: Exploring New Possibilities first appeared on CADD Centre Resource.

Building Information Modeling simplifies incorporation, compatibility and connection in the construction industry by providing a 3D view of a project containing all parameters and its mechanisms. It is ideal for transferring information to improve building design and presentation. Different BIM-based software, used depending on the job and needs, results in data loss during the information exchange process and unwanted duplication of job data retrieval.

BIM Course enhances knowledge sharing management, reducing the time and cost of solving problems related to constructability and project coordination. In addition, it allows architects and structural engineers to visualize modifications and conflicts and assists immediate decision making, significantly reducing rework and optimizing project times and costs. Also, by detecting errors in advance and automating variables that were traditionally used in “manual” processes, BIM enhances automation of detail engineering and documentation processes, reducing work times and increasing project quality.

In some developed countries of the Americas and Europe, the number of construction projects using BIM technology has exceeded that of traditional construction projects. Architects and engineers share information more effectively related to sustainability with the help of BIM applications, such as daylighting and energy consumption, and thus the sustainability analysis can be seamlessly integrated into the design process. BIM is also helpful for designers to utilize the existing building data to improve the default configuration of building early stages of new building design. BIM software provides efficient solutions to ease the environmental effects of the construction process.

The various factors which affect the energy use of a building include building location, size and shape and its parts. In internal spaces, heat and light occurred which reduces the need for energy use. It results in improved efficiency and reduced energy use by reducing heating and lighting units. In the energy simulation process, BIM is considered an important factor for users to create a high

potential in sustainable building design. Thus, evaluate the energy performance effectively before constructing the building on site.

The post How does BIM technology help with energy-saving design methods? first appeared on CADD Centre Resource.

The Responsibilities of a Civil Engineer

A civil engineer may be concerned with several tasks. The civil engineer is responsible for planning and supervising the construction and renovation of structures, rail and road projects, and local and national infrastructure.

It is a diverse field with great scope and added prestige. There is usually going to be a want for well-certified civil engineers, making this profession one of the maximum futuristic selections to stand the check of time.

Challenging Gender Stereotypes

Even though the number of women in engineering has increased, most girls are attracted to IT or computer science. Civil engineering is traditionally male-dominated industry, as this profession requires not only manual skills but also physical stamina.

However, with major advances in technology, this is no longer a barrier for  girls to pursue a career in civil engineering.

Women in Indian Civil Engineering

In India, women make up the workforce at many construction sites but at an engineering school, few girls choose this branch. Determined to break stereotypes, several girls take the course and volunteer for a job. where they have to work on a construction site. When it comes to choosing a field like construction, mechanical, or electrical, girls are confronted with statements like “this field is not for you”.

Overcoming Stereotypes

All girls wishing to embark on a civil engineering path should not hesitate only because of the line drawn by the society of the division of sectors according to gender.

If you have the attitude, nothing can stop you from achieving your goal. Women can work their qualities to their advantage working in a civil engineering sector because of following reasons.

1. Unique Perspective and Creativity

Women can bring a different perspective when designing and executing a project, which will have a huge positive impact on creating aesthetically appealing structures.

2. Multitasking Abilities

Women are known for their multitasking abilities. It may not be easy for women to break into civil engineering, but it’s not as hard as it sounds. Today we have several prolific female engineers who have made their mark with their intelligence.

3. Leveraging Unique Qualities

The post Top Reasons Women Should Pursue Civil Engineering first appeared on CADD Centre Resource.

The top CAM softwares are:

• Fusion 360 – This is for product designers, mechanical engineers, electrical engineers, and machinists. It consolidates design, engineering, PCB design, and manufacturing into a single platform. It allows the user to connect their disconnected product development process to deliver high-quality products to market faster and create a positive impact.
• Solid Edge – This software is a set of affordable, easy to deploy, maintain, and use software tools that advance all aspects of the product development processes such as mechanical and electrical design, simulation, manufacturing, technical documentation, data management, and cloud-based collaboration.
• CAMWorks – CAMWorks is an intuitive, feature-based CAM software that helps in increasing productivity using best-in-class technologies and adaptable automation tools to maximize CNC machining efficiency.
• HSM – Inventor HSM and HSMWorks CAM software simplify the machining workflow with CAD-embedded 2.5-axis to 5-axis milling, turning, and mill-turn capabilities. Available only as part of the Product Design & Manufacturing Collection.
• NX CAM – It provides comprehensive and integrated NC programming capabilities in a single system enabling the use of consistent 3D models, data, and processes to seamlessly connect digital thread with planning and shop floor operations.
• FeatureCAM – FeatureCAM software automates workflow from design to NC code. It automatically recognizes holes, bosses, sides, and pockets in a single workflow for faster programming.
• SolidCAM – SolidCAM is software that runs directly inside the existing SolidWorks CAD design or Autodesk Inventor CAD system with seamless integration and full tool path associativity.
• Cimatron – Cimatron addresses the entire tool-making process from quoting to design, applying engineering changes and NC programming, and delivers major advantages for mold, die, and manufacturing shops keeping.
• Autodesk Product Design & Manufacturing Collection – Including in-canvas workflows for design, advanced simulation, 5-axis CAM, nesting, and factory layout design and make your products with the best collection. There is also access to specialized toolsets available with AutoCAD, along with new cloud-based technologies like Fusion 360.

The post Top solutions for computer-aided manufacturing first appeared on CADD Centre Resource.

1. Industry-specific training helps you to strengthen your skills as per the industry demand and employer needs.
2. It keeps you updated with the latest trends and technologies with a combination of practical and theory classes.
3. It provides a lifelong learning experience along with an opportunity to build networks with industry professionals.
4. People who take the right training need lesser supervision and guidance. Therefore, the chances of getting hired are more. It increases the future employment prospects.
5. It provides learners hands-on practice and valuable experiences of working in a professional workplace environment.
6. It helps increase your self-confidence and makes you proficient in your respective domain.
7. Industry-specific training helps in increasing productivity and adherence to quality standards.

In a nutshell, industry-specific training increases your knowledge and makes you ready for the competitive corporate environment.

The post Why is Industry Specific Training important? first appeared on CADD Centre Resource.

• A survey revealed that 43% of women in technology are paid less than men.
• 39% of the women indicated that they experience gender bias at their workplace.
• 48% of women claimed that lack of mentors weakens the state of women.
• 42% of the women said they experience a slow growth rate due to a lack of female role models.

The data mentioned above is not very overwhelming. Despite being born in this hi-tech era, if we suffer from such gender bias, it is the biggest weakness of society. This inequality in career prospects is not only restraining women but is also hindering the growth of the Technology Industry.

Depleting IT Industry

Fewer opportunities for women in the tech industry have diverted the women workforce towards alternative career options. As a result, the information technology sector is suffering from a shortage of skilled workers in engineering and technical domains. This lack of workforce is restricting the overall growth and development of the industry.

Empowering Women

Considering the criticality of the situation, it is necessary for organizations to take strict measures to promote women’s inclusion in the industry. Given below are a few measures which could help bring women back into the IT sector.

1. Create a network to connect talented female employees with other inspirational female motivators.
2. The inclusion of women in the executive team will boost their confidence. Additionally, this involvement will motivate other women to strive for career growth.
3. Allocating mentors helps in the overall development of the female workforce.

In a nutshell, we can say that women are an integral part of society and the corporate world. Their diversion from the technology domain is a huge drawback for the industry. As a result, strict measures must be taken to bring women to the mainstream information technology sector.

The post Lack of Women in Tech is Hindering Industry Growth first appeared on CADD Centre Resource.

In the ever-evolving landscape of technology, the design industry is undergoing a profound shift in its requirements. To meet the demands of this dynamic environment, designers and engineers now require tools and applications that are not just adaptable but also highly responsive to the evolving product design process. Among these transformative technologies, SolidWorks has emerged as a game-changer in the field of engineering design in recent years.

Embracing Innovation in Industry Design

SolidWorks has embraced a holistic approach to design by incorporating social, collaborative, and conceptual methods into the design experience. Its design philosophy is built on empowering engineers with powerful and easily accessible technologies that streamline the design process while delivering significant business advantages.

Overcoming Traditional Design Challenges

Before the advent of SolidWorks in the engineering design field, designers faced numerous challenges. These challenges included extensive rework, data incompatibility, limited flexibility, slow processing times, disconnection between industrial and mechanical designs, and difficulty in evaluating multiple design concepts. These roadblocks resulted in low efficiency and delayed time to market.

The Power of Free Form Design

One of SolidWorks’ most promising features is its ability to blend traditional modeling techniques with advanced free-form methods. The SolidWorks Industrial Design package provides engineers with the capability to create precise and easily navigable designs. This application removes the aforementioned barriers by offering an intuitive modeling environment that enhances the overall industrial design process.

Advanced SolidWorks Capabilities and Data Management

SolidWorks Industrial Design is equipped with advanced design capabilities and transparent data management. These features enable engineers and designers to swiftly resolve industrial design challenges and produce structures that can seamlessly transition into mechanical models. With the SolidWorks Industrial Design application, engineering professionals are now able to create intricate 3D designs and incorporate mechanical data directly, eliminating the need for additional rework during the transformation into mechanical models.

SolidWorks: Transforming the Mechanical Design Industry

SolidWorks has not only transformed the field of mechanical design but has also made it safer, quicker, and more accessible than ever before. As a result, there is a growing demand for certified SolidWorks professionals across organizations. If you’re eager to explore the world of SolidWorks Industrial Design and unlock lucrative career opportunities, consider enrolling in the Advanced SolidWorks Training offered by the CADD Centre. Their industry-oriented and market-focused certifications can propel engineering design professionals to new heights in their careers.

Conclusion

In a world where technological innovation is the driving force behind progress, SolidWorks stands as a beacon of change in the engineering design landscape. It has addressed the shortcomings of traditional design methods and ushered in an era of efficiency, collaboration, and innovation. As the demand for professionals skilled in solidWorks software continues to rise, now is the perfect time to embark on a journey of learning and growth with SolidWorks.

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Innovation in Engineering – Need of the Hour

Technology advancement is in air from so long, knotted almost every single part of our lives. It affects our routines, how people shop, connect, learn, socialize, and play everything. Technology is a giant contributor to the well-being of society. And it has proven itself to be very valuable.

India has been at the front position of the back end of this revolution of innovation in Engineering. A rapid change and development in technology demands the educated and well trained workforce. While engineering study is a key driver for a systematic learning of the practices working in industry, agriculture, and commerce. Innovation in the material, procedures, and patterns of education is the crying need to meet the expectations. Modern engineers use CAD systems throughout the design and testing processes. These studies are then put together to practise in order to make routines much easier. Every stream does have a need of persistent monitoring to recognize areas for possible development, so as engineering too. Engineering in India is still stuck in the industrialised age – assembly line methods inform our education. Education System should go forward for a need to feed the industrial unit, Engineering and management education should upgrade procedures to furnish people and prepare a force who could follow commands and withstand in monotonous procedures. The need of hour is a reliable updation on ongoing basis to grow and run the nation or organization smoothly.

The Indian education market being too nascent to support the industry. In fact currently, the innovators are stepped back due to the hurdles presented by a recent market. Somehow or the other, breadwinners found ways to avoid hurdles in the system, but others still lacking behind.

We are breathing in a constantly changing world. New technologies are emerging every day and if you don’t desire to be left behind, always keep up with the changing scenario. Without innovation in education it will be actually tough to adapt to all these deviations. Simultaneously, this should be acknowledged that engineering is the future of nation and its overall development. Education giants responded to the needs of the companies and skilled students in performing task based activities. They should learn to respect hierarchies – which represent both authority and ambition. A well educated person is well aware of the modern technologies and the changes that are taking place in the world, if educated accordingly.

Image courtesy: shortsleeveandtieclub.com

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“Make in India” Expands Scope for Engineers

Make in India is an initiative by Prime Minister- Mr. Narendra Modi that focuses on 25 sectors of the economy for skills enhancement and job creation. The list includes: IT, textiles, chemicals, tourism and hospitality, automobiles, pharmaceuticals, ports, aviation, bio-technology, leather, wellness, design manufacturing, mining, railways, renewable energy, and electronics. The initiative is expected to drive an increase in tax revenue and GDP growth.

With the bell of ‘Make in India’, any industry which requires monitoring, sensing and controlling of variables has rapidly growing employment opportunities in the horizon; and it’s time for engineers to take it on a serious note . Areas like process automation, factory automation, manufacturing industries (testing, design, and quality control), consultants (turnkey projects /solution providers), system engineering, embedded systems and electronic circuit plan uncover the plenty of job opportunities for engineers via this initiative.

Before the initiative was introduced, foreign equity caps in many sectors had been relaxed. The request for licenses was made accessible online and the strength of licenses was increased to 3 years. The initiative also targets at quality standards and reducing the impact on the nature. The initiative hopes to attract capital and technological investment in India.

Some Promising Numbers

Out of 25 sectors, except Defence (49%) Space (74%), and Media (26%), 100% Foreign Direct Investment is allowed in the rest of the sectors.

Below listed Business giants investing under the Make in India plan which may benefit engineers to breathe their dreams:

1. The Spice Group will initiate a mobile phone manufacturing unit in Uttar Pradesh(UP) with an investment of Rs.500 crore.

2. Samsung INS coming up with a joint initiative under which 10 “MSME-Samsung Technical Schools” will be started in India. In February, Samsung said that will produce the Samsung Z1 in its plant in Noida.

3. Hitachi would increase its workforces in India from 10,000 to 13,000.

4. Huawei opened a new research and development campus in Bengaluru. It had capitalized US$170 million to launch the research and development centre.

5. Marine Products Export Development Authority said that it was concerned in supplying shrimp eggs to farmers in India.

6. France-based LH Aviation contracted a MoU with OIS Advanced Technologies to establish a manufacturing plant in India to manufacture drones.

India’s technical talent is second to none. Indian technical forces have expertise that cannot be found anywhere else around the globe. Specifically, Indians do have a rare capacity for creating creative resolutions with limited resources when compared with the engineers in the West. If the prime minister is giving his full support to the manufacturing sector through the Make in India movement, career openings must be explored far beyond what was previously thought possible for Engineers.

Image courtesy:  www.engineersindia.com

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