- So far we have defined work done by a force which is constant in both magnitude and direction.
- However, work can be done by forces that varies in magnitude and direction during the displacement of the body on which it acts.
Showing posts with label KEAM. Show all posts
Showing posts with label KEAM. Show all posts
WORK, ENERGY AND POWER - STUDY MATERIAL 2
KEAM RESULTS ON 20 MAY
Keam result will be published on 20th May 2015.
The rank list for Kerala medical entrance examination and score for engineering entrance examination will be published on May 20.
The rank list for Kerala medical entrance examination and score for engineering entrance examination will be published on May 20.
KEAM 2014 FITNESS CERTIFICATE FORM
The fitness certificate can be downloaded by clicking the link given below. Fitness Certificate is needed while seeking admission in the professional engineering courses.
Certificates regarding the physical standards/fitness prescribed may be obtained from a Medical Officer in service not below the rank of an Assistant Surgeon in the concerned.
Certificates regarding the physical standards/fitness prescribed may be obtained from a Medical Officer in service not below the rank of an Assistant Surgeon in the concerned.
KEAM 2014 THIRD ALLOTMENT RESULTS
Keam Third Allotment results published on 19th July 2014. Check the allotment results by clicking the link given below.
www.cee.kerala.gov.in
Those getting an allotment will have to remit the fee shown in the allotment memo at selected branches of State Bank of Travancore (SBT) between 24th July and 25th July 2014. Those candidates who do not remit the fee on or before this prescribed date will lose their allotment as well as the eligibility for further allotments in all streams.
Steps to follow to get this result
1. Click the link given above
2. Enter the application no
3. Enter the roll no
4. Enter the key no
5. Enter the password
6. press "Enter"
The last rank details of the keam 2014 first allotment results can be download from here by clicking the download button.
www.cee.kerala.gov.in
Those getting an allotment will have to remit the fee shown in the allotment memo at selected branches of State Bank of Travancore (SBT) between 24th July and 25th July 2014. Those candidates who do not remit the fee on or before this prescribed date will lose their allotment as well as the eligibility for further allotments in all streams.
Steps to follow to get this result
1. Click the link given above
2. Enter the application no
3. Enter the roll no
4. Enter the key no
5. Enter the password
6. press "Enter"
The last rank details of the keam 2014 first allotment results can be download from here by clicking the download button.
KEAM 2014 ALLOTMENT CANCELLATION
Students which get allotment in any of the keam allotments can cancel their allotment.Those Students who cancel the allotment will be out of the furthur keam allotment process. Students who have no interest in engineering can cancel their options.Keam allotment cancellation could not be used to cancel their second allotment results.Cancel keam allotment from the below link .
http://cee.kerala.gov.in
Care should be taken while cancelling allotment.You will be out of the furthur allotment process.
Steps to taken while deleting allotment
1. login to the account
2. Enter the application number
3. Enter the roll number
4. Enter the key number
5. Click submit button
6. Cancel the options
http://cee.kerala.gov.in
Care should be taken while cancelling allotment.You will be out of the furthur allotment process.
Steps to taken while deleting allotment
1. login to the account
2. Enter the application number
3. Enter the roll number
4. Enter the key number
5. Click submit button
6. Cancel the options
KEAM 2014 SECOND ALLOTMENT RESULTS
Keam Second Allotment results published on 19th July 2014. Check the allotment results by clicking the link given below.
www.cee.kerala.gov.in
Those getting an allotment will have to remit the fee shown in the allotment memo at selected branches of State Bank of Travancore (SBT) between 20th July and 21st July 2014. Those candidates who do not remit the fee on or before this prescribed date will lose their allotment as well as the eligibility for further allotments in all streams.
Steps to follow to get this result
1. Click the link given above
2. Enter the application no
3. Enter the roll no
4. Enter the key no
5. Enter the password
6. press "Enter"
The last rank details of the keam 2014 first allotment results can be download from here by clicking the download button.
www.cee.kerala.gov.in
Those getting an allotment will have to remit the fee shown in the allotment memo at selected branches of State Bank of Travancore (SBT) between 20th July and 21st July 2014. Those candidates who do not remit the fee on or before this prescribed date will lose their allotment as well as the eligibility for further allotments in all streams.
Steps to follow to get this result
1. Click the link given above
2. Enter the application no
3. Enter the roll no
4. Enter the key no
5. Enter the password
6. press "Enter"
The last rank details of the keam 2014 first allotment results can be download from here by clicking the download button.
KEAM 2014 SECOND PHASE OPTION REGISTRATION
Online option for Kerala engineering agricultureexaminations
The candidates who have Engineering,Medical, and Architecture Rankcan the options.
To register options goto the below link
http://cee.kerala.gov.in
Candidate should read clause 11.4 and 11.5 before register their options.
KEAM Option Registration 2014 Last Date – 17 July 2014 (5 PM).
The allotment in this phase will be published on 19th July 2014.
Those candidates who receive allotment can remit the Tuition Fee /Token Amount in selected branches of State Bank of Travancore on 26th June to 3rd July 2014 .
Those who do not remit fee in the specified time will lose their existing allotment.
Allotment to all courses will be subject to Govt. Sanction/Permission of the Apex body/Affiliation from the University
concerned.
Candidates retaining unnecessary higher options, in colleges which
they do not wish to join, will be liable to pay penalty as per Clause
12.2.4(c) of the prospectus.
BIOTECHNICAL ENGINEERING
Biotechnology involves the handling and manipulation of living organisms or their components to produce useful products. Students specializing in biotechnical engineering integrate analysis and design with applied biology to solve problems in renewable energy production, large-scale biotechnical production, control of biological systems, and production of bio-based materials.
Students may focus on the mechanisms and processes for the sustainable production and use of energy from renewable biological sources. Students may also focus on the challenges in scaling up laboratory developments to industrial production, including genetically altered plants, plant materials and food products; production, packaging, and application of biocontrol agents for plant pests and diseases; and microbial production of biological products, tissue culture, and bioremediation. Students may also focus on the development of biosensors to detect microorganisms and specific substances, useful in the development of products based on biological processes and materials.
Biotechnical engineers work in the biotech industries on process design and operation, scale-up, and instrumentation and control.
BIOMEDICAL ENGINEERING
Biomedical engineering (BME) is the application of engineering principles and design concepts to medicine and biology for healthcare purposes (e.g. diagnostic or therapeutic). This field seeks to close the gap between engineering and medicine: It combines the design and problem solving skills of engineering with medical and biological sciences to advance healthcare treatment, including diagnosis, monitoring, and therapy.
Biomedical engineering has only recently emerged as its own study, compared to many other engineering fields. Such an evolution is common as a new field transitions from being an interdisciplinary specialization among already-established fields, to being considered a field in itself. Much of the work in biomedical engineering consists of research and development, spanning a broad array of subfields (see below). Prominent biomedical engineering applications include the development of biocompatible prostheses, various diagnostic and therapeutic medical devices ranging from clinical equipment to micro-implants, common imaging equipment such as MRIs and EEGs, regenerative tissue growth, pharmaceutical drugs and therapeutic biologicals
Biomedical engineering has only recently emerged as its own study, compared to many other engineering fields. Such an evolution is common as a new field transitions from being an interdisciplinary specialization among already-established fields, to being considered a field in itself. Much of the work in biomedical engineering consists of research and development, spanning a broad array of subfields (see below). Prominent biomedical engineering applications include the development of biocompatible prostheses, various diagnostic and therapeutic medical devices ranging from clinical equipment to micro-implants, common imaging equipment such as MRIs and EEGs, regenerative tissue growth, pharmaceutical drugs and therapeutic biologicals
ARCHITECTURAL ENGINEERING
Architectural engineering, also known as building engineering, is the application of engineering principles and technology to building design and construction. Definitions of an architectural engineer may refer to:
An engineer in the structural, mechanical, electrical, construction or other engineering fields of building design and construction.
A licensed engineering professional in parts of the United States.
In informal contexts, and formally in some places, a professional synonymous with or similar to an architect.
What differentiates architectural engineering as a separate and single, integrated field of study, compared to other engineering disciplines, is its multi-disciplinary engineering approach. Through training in and appreciation of architecture, the field seeks integration of building systems within its overall building design. Architectural engineering includes the design of building systems including heating, ventilation and air conditioning (HVAC), plumbing, fire protection, electrical, lighting, architectural acoustics, and structural systems. In some university programs, students are required to concentrate on one of the systems; in others, they can receive a generalist architectural or building engineering degree.
An engineer in the structural, mechanical, electrical, construction or other engineering fields of building design and construction.
A licensed engineering professional in parts of the United States.
In informal contexts, and formally in some places, a professional synonymous with or similar to an architect.
What differentiates architectural engineering as a separate and single, integrated field of study, compared to other engineering disciplines, is its multi-disciplinary engineering approach. Through training in and appreciation of architecture, the field seeks integration of building systems within its overall building design. Architectural engineering includes the design of building systems including heating, ventilation and air conditioning (HVAC), plumbing, fire protection, electrical, lighting, architectural acoustics, and structural systems. In some university programs, students are required to concentrate on one of the systems; in others, they can receive a generalist architectural or building engineering degree.
AUTOMOBILE ENGINEERING
Modern automobile engineering, along with aerospace engineering and marine engineering, is a branch of vehicle engineering, incorporating elements of mechanical, electrical, electronic, software and safety engineering as applied to the design, manufacture and operation of motorcycles, automobiles, buses and trucks and their respective engineering subsystems.
Automobile engineers hold a wide variety of responsibilities. Their primary purpose is to maximize the feasibility and design of automobiles keeping costs to an absolute minimum.
A typical professional in this field spends a lot of time on researching and designing both systems and machines for automobiles. The designs are initially done in the form of drawings and blueprints. Automobile engineers then apply physical and mathematical principles to these plans to make sure they are viable. The planning is done after considerable research, and then altered again after linking the plans to the available research.
A graduate engineer at a major OEM (original equipment manufacturer, ie carmaker) gets a stipend of Rs. 28,000 to Rs. 30,000 a month during training. This can go up to Rs. 40,000 till s/he is confirmed. A line leader/assistant manager can earn anything from Rs. 40,000 to Rs. 80,000 a month, depending on their experience in the industry.
Automobile engineers hold a wide variety of responsibilities. Their primary purpose is to maximize the feasibility and design of automobiles keeping costs to an absolute minimum.
A typical professional in this field spends a lot of time on researching and designing both systems and machines for automobiles. The designs are initially done in the form of drawings and blueprints. Automobile engineers then apply physical and mathematical principles to these plans to make sure they are viable. The planning is done after considerable research, and then altered again after linking the plans to the available research.
A graduate engineer at a major OEM (original equipment manufacturer, ie carmaker) gets a stipend of Rs. 28,000 to Rs. 30,000 a month during training. This can go up to Rs. 40,000 till s/he is confirmed. A line leader/assistant manager can earn anything from Rs. 40,000 to Rs. 80,000 a month, depending on their experience in the industry.
COMPUTER SCIENCE AND ENGINEERING
computer science and engineering is a discipline that integrates several fields of electrical engineering and computer science required to develop computer hardware and software.Computer engineers usually have training in electronic engineering (or electrical engineering), software design, and hardware-software integration instead of only software engineering or electronic engineering. Computer engineers are involved in many hardware and software aspects of computing, from the design of individual microprocessors, personal computers, and supercomputers, to circuit design. This field of engineering not only focuses on how computer systems themselves work, but also how they integrate into the larger picture.
Usual tasks involving computer engineers include writing software and firmware for embedded microcontrollers, designing VLSI chips, designing analog sensors, designing mixed signal circuit boards, and designing operating systems. Computer engineers are also suited for robotics research, which relies heavily on using digital systems to control and monitor electrical systems like motors, communications, and sensors.
In many institutions, computer science and engineering students are allowed to choose areas of in-depth study in their junior and senior year, because the full breadth of knowledge used in the design and application of computers is beyond the scope of an undergraduate degree. Other institutions may require engineering students to complete one year of General Engineering before declaring computer science and engineering as their primary focus.
Usual tasks involving computer engineers include writing software and firmware for embedded microcontrollers, designing VLSI chips, designing analog sensors, designing mixed signal circuit boards, and designing operating systems. Computer engineers are also suited for robotics research, which relies heavily on using digital systems to control and monitor electrical systems like motors, communications, and sensors.
In many institutions, computer science and engineering students are allowed to choose areas of in-depth study in their junior and senior year, because the full breadth of knowledge used in the design and application of computers is beyond the scope of an undergraduate degree. Other institutions may require engineering students to complete one year of General Engineering before declaring computer science and engineering as their primary focus.
CHEMICAL ENGINEERING
Chemical engineering is a branch of engineering that applies the natural (or experimental) sciences (e.g. chemistry and physics) and life sciences (e.g. biology, microbiology and biochemistry) together with mathematics and economics to produce, transform, transport, and properly use chemicals, materials and energy. It essentially deals with the engineering of chemicals, energy and the processes that create and/or convert them. Modern chemical engineers are concerned with processes that convert raw materials or (cheap) chemicals into more useful or valuable forms. They are also concerned with pioneering valuable materials and related techniques – which are often essential to related fields such as nanotechnology, fuel cells and bioengineering.
CIVIL ENGINEERING
Civil engineering is a professional engineering discipline that deals with the design, construction, and maintenance of the physical and naturally built environment, including works like roads, bridges, canals, dams, and buildings. Civil engineering is the second-oldest engineering discipline after military engineering, and it is defined to distinguish non-military engineering from military engineering. It is traditionally broken into several sub-disciplines including architectural engineering, environmental engineering, geotechnical engineering, geophysics, geodesy, control engineering, structural engineering, transportation engineering, earth science, atmospheric sciences, forensic engineering, municipal or urban engineering, water resources engineering, materials engineering, offshore engineering, quantity surveying, coastal engineering, surveying, and construction engineering. Civil engineering takes place in the public sector from municipal through to national governments, and in the private sector from individual homeowners through to international companies.
AERONAUTICAL ENGINEERING
Aeronautical engineering is the primary branch of engineering concerned with the research, design, development, construction, testing, science and technology of aircraft and spacecraft. Aeronautics deals with aircraft that operate in Earth's atmosphere, and astronautics deals with spacecraft that operate outside the Earth's atmosphere.
Aeronautical engineering deals with the design, construction, and study of the science behind the forces and physical properties of aircraft, rockets, flying craft, and spacecraft. The field also covers their aerodynamic characteristics and behaviors, airfoil, control surfaces, lift, drag, and other properties.
An aeronautical, or aerospace, engineer applies scientific and technological principles to research, design, develop, maintain and test the performance of:
civil and military aircraft;
missiles;
weapons systems;
satellites;
space vehicles.
They also work on the different components that make up these aircraft and systems.
The role is focused on improving flight safety, fuel efficiency, speed and weight, as well as reducing system costs and using advancing technologies to meet customer needs. Increasingly, the role addresses the environmental impact of air travel.
Aeronautical engineering deals with the design, construction, and study of the science behind the forces and physical properties of aircraft, rockets, flying craft, and spacecraft. The field also covers their aerodynamic characteristics and behaviors, airfoil, control surfaces, lift, drag, and other properties.
An aeronautical, or aerospace, engineer applies scientific and technological principles to research, design, develop, maintain and test the performance of:
civil and military aircraft;
missiles;
weapons systems;
satellites;
space vehicles.
They also work on the different components that make up these aircraft and systems.
The role is focused on improving flight safety, fuel efficiency, speed and weight, as well as reducing system costs and using advancing technologies to meet customer needs. Increasingly, the role addresses the environmental impact of air travel.
AGRICULTURAL ENGINEERING
Agricultural engineering is the engineering discipline that applies engineering science and technology to agricultural production and processing. Agricultural engineering combines the disciplines of mechanical, civil, electrical and chemical engineering principles with a knowledge of agricultural principles
Agricultural engineers may perform tasks as planning, supervising and managing the building of dairy effluent schemes, irrigation, drainage, flood and water control systems, performing environmental impact assessments, agricultural product processing and interpret research results and implement relevant practices. A large percentage of agricultural engineers work in academia or for government agencies such as the United States Department of Agriculture or state agricultural extension services. Some are consultants, employed by private engineering firms, while others work in industry, for manufacturers of agricultural machinery, equipment, processing technology, and structures for housing livestock and storing crops. Agricultural engineers work in production, sales, management, research and development, or applied science.
Agricultural engineers may perform tasks as planning, supervising and managing the building of dairy effluent schemes, irrigation, drainage, flood and water control systems, performing environmental impact assessments, agricultural product processing and interpret research results and implement relevant practices. A large percentage of agricultural engineers work in academia or for government agencies such as the United States Department of Agriculture or state agricultural extension services. Some are consultants, employed by private engineering firms, while others work in industry, for manufacturers of agricultural machinery, equipment, processing technology, and structures for housing livestock and storing crops. Agricultural engineers work in production, sales, management, research and development, or applied science.
APPLIED ELECTRONICS & INSTRUMENTATION
B.Tech Applied Electronics and Instrumentation is an undergraduate course in engineering. The duration of the course is 4 years. The main objective of the course is to develop skilled engineering graduates who are able to perform well in the application areas of process control and instrumentation. The students are exposed to theoretical and practical training in design and operation of digital logic system, electronic instruments, etc. By pursuing the course, the candidate gain skills to do well in areas of industrial electronics and its applications. Apart from this, the candidate becomes competent in areas of microprocessor and microcontroller design, its operation, maintenance and so on.
The course study offers adequate technical proficiency to the student community and there by enhancing the productivity of industrial sector. Skilled professionals can contribute new and innovative ideas to electronics sector. This can cause a positive impact in the development of electronics in the corporate world. Apart from this, interested students can continue their studies in application areas of Electronics. They can also find a lucrative career either in governmental or private sector.
The demand for candidates who have completed their bachelor degree in Applied Electronics and Instrumentation is increasing at a fast pace. These candidates can work in engineering section or in quality control section of companies. They can work in research and development organizations and also in educational sector. Firms that deal with the manufacture and maintenance of electronics and process control equipments are in great need of these candidates. Apart from private sector jobs, the candidates can apply for jobs in public sector firms also.
The course study offers adequate technical proficiency to the student community and there by enhancing the productivity of industrial sector. Skilled professionals can contribute new and innovative ideas to electronics sector. This can cause a positive impact in the development of electronics in the corporate world. Apart from this, interested students can continue their studies in application areas of Electronics. They can also find a lucrative career either in governmental or private sector.
The demand for candidates who have completed their bachelor degree in Applied Electronics and Instrumentation is increasing at a fast pace. These candidates can work in engineering section or in quality control section of companies. They can work in research and development organizations and also in educational sector. Firms that deal with the manufacture and maintenance of electronics and process control equipments are in great need of these candidates. Apart from private sector jobs, the candidates can apply for jobs in public sector firms also.
ENGINEERING COURSE DETAILS
KEAM, short for Kerala Engineering Agricultural Medical is an entrance examination series for admissions to various professional degree courses in the state of Kerala, India. It is conducted by the Office of the Commissioner of Entrance Exams run by the Government of Kerala.
The following were the courses offered by KEAM and CEE-Kerala .Click the link to get more details about the course.
Applied Electronics
Agricultural Engineering
Aeronautical Engineering
Automobile Engineering
Architecture
Bio Medical Engineering
Bio Technology
Civil Engineering
Chemical Engineering
Computer Science & Engineering
Dairy Science & Tech.
Electronics & Communication Engineering
Electrical & Electronics Engineering
Electronics & Instrumentation Engineering
Food Engineering
Safety & Fire Engineering
Food Technology
Instrumentation & Control Engg.
Industrial Engineering
Information Technology
Mechanical (Automobile)
Mechanical Engineering
Mechanical (Prodn. Engg.)
Mechatronics Engineering
Metallurgy
Production Engineering
Polymer Engg.
Printing Technology.
Naval Architecture & Ship Building
The following were the courses offered by KEAM and CEE-Kerala .Click the link to get more details about the course.
Applied Electronics
Agricultural Engineering
Aeronautical Engineering
Automobile Engineering
Architecture
Bio Medical Engineering
Bio Technology
Civil Engineering
Chemical Engineering
Computer Science & Engineering
Dairy Science & Tech.
Electronics & Communication Engineering
Electrical & Electronics Engineering
Electronics & Instrumentation Engineering
Food Engineering
Safety & Fire Engineering
Food Technology
Instrumentation & Control Engg.
Industrial Engineering
Information Technology
Mechanical (Automobile)
Mechanical Engineering
Mechanical (Prodn. Engg.)
Mechatronics Engineering
Metallurgy
Production Engineering
Polymer Engg.
Printing Technology.
Naval Architecture & Ship Building
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