hello

hi look these two frequent questions of electronic enginnering:
1. Why study Engineering?
Engineering is directly responsible for the development of communities, peoples and nations. A country with engineers, guarantees a prosperous future that aims to create optimum conditions of health, housing, transportation, education, communications, industrial development, among others. Engineering is studied to improve the quality of life of people.

2. What is the Electronic Engineering Degree?
It is the discipline that is responsible for conceiving, designing and implementing technology solutions aplicacbles to telecommunications, signal processing, control and process automation, robotics, digital or computer systems, bioengineering and the development of electronic devices. These solutions arise from information processing and conditioning and power optimization.

hiiiii friends

hi friends check out this video of electricity and magnetism, such a topic that I like and important of electronic engineering

hi

be careful with oil because this can affect economically, environmentally, socially ...http://www.youtube.com/watch?v=lZ0JkVMTyC4

http://www.youtube.com/watch?v=bWhet5eHuBM&feature=related

Maria Juliana Piedrahita 

andes university

check the Andes Pensum of electronic engineering 

Ciclo Básico

Primer Semestre
Cálculo 10
Química 11
Sistemas de Representaciòn 10
Humanidades (Ciencia y Tecnología)

Segundo Semestre
Cálculo 20
Física 10
Sistemas de Representación 20
Estadística 

Tercer Semestre
Cálculo 30
Física 20
Lab. Física General
Electricidad y Magnetismo
Programación Digital

Electivas del Ciclo Básico:
Lengua y Comunicación I
Lengua y Comunicación II
Ingles  Lectura I
Ingles  Lectura II
Desarrollo Habilidades del Pensamiento
Lectura Crítica

Ciclo Profesional:

Cuarto Semestre  
Cálculo 40
Mecánica Racional
Introducción a la Ingeniería Eléctrica
Circuitos Eléctricos I
Redacción de Informes  

Quinto SemestreMatemáticas Especiales
Electrónica I
Fundamentos de las Mediciones
Circuitos Eléctricos II
Sistemas Digitales 

Sexto Semestre
Campos Electromagnéticos
Electrónica II  
Laboratorio de Electrónica I
Circuitos Eléctricos III
Laboratorio de Circuitos
Máquinas Eléctricas I

Séptimo Semestre
Sistemas Lineales 
Electrónica III 
Laboratorio de Electrónica II
Sistemas de Transmisión
Lab. de Máquinas Eléctricas I
Máquinas Eléctricas II

Octavo Semestre
Comunicaciones I
Sistemas de Control
Laboratorio de Electrónica III
Mediciones Eléctricas
Lab. de Máquinas Eléctricas II
Sistemas de Potencia I 

Noveno Semestre
Instalaciones Eléctricas
Laboratorio I de Control
Ingeniería Económica
Electiva
Electiva 

Décimo Semestre
Relaciones Industriales
Electiva
Electiva
Trabajo de Grado

Materias Electivas
Departamento de Circuitos y Medidas
Automatización de Mediciones
Instrumentación Industrial
Instrumentación Biomédica
Instrumentación Inteligente
Compatibilidad Electromagnética
Control Digital
Control Avanzado
Pasantías

Departamento de Potencia
Construcción de Líneas
Control de Motores Eléctricos
Máquinas Eléctricas III
Sistemas de Distribución
Sistemas de Potencia II
Sistemas de Protección
Subestaciones Eléctricas
Centrales Eléctricas
Ingeniería de Alta Tensión
Pasantías

Departamento de Electrónica
y Comunicaciones
Comunicaciones Digitales
Circuitos Integrados
Electrónica Industrial
Laboratorio de Comunicaciones
Laboratorio de Sistemas Digitales
Física Electrónica
Máquinas Secuenciales
Microondas
Microprocesadores
Procesamiento Digital de Señales
Propagación y Antenas
Radioenlaces 
Diseño Interfases p/Comp. Personales
Telefonía
Transmisión Óptica 
Redes de Computadoras
Técnicas de Pulsos
Pasantías

check this video

http://www.youtube.com/watch?v=cTyBHniLtcw&feature=related
Maria juliana Piedrahita 11C

hello the works of electronic engineer

 Heloo check the Typical work and  activities of the electronic engineer

Electronics engineers work on a project through all its stages: from the initial brief for a concept; through the design and development stage; to the testing of one or more prototypes; and through to final manufacture and implementation of a new product or system.
The exact duties vary, depending on the industry, but tasks typically include:

• discussing proposals with clients;
• working with colleagues to design new systems, circuits and devices or develop existing technology;
• testing theoretical designs;
• writing specifications;
• following defined development processes;
• systematically improving the detailed design of a piece of electronic equipment;
• ensuring that a product will work with devices developed by others, can be made again reliably, and will perform consistently in specified operating environments;
• creating user-friendly interfaces;
• ensuring safety regulations are met;
• project planning and preparing budgets;
• attending meetings with sub-contractors;
• supervising technicians and craftspeople and other colleagues;
• writing technical reports;
• keeping up to date with developments in technologies and regulations.

There are two main types of graduate electronic engineer. Chartered Engineers (CEng) have the greatest level of responsibility for engineering projects. They develop solutions to problems using new or existing technologies. Incorporated Engineers (IEng) take responsibility for specific aspects of a project. They maintain and manage applications of current and developing technology.

look the professional bodies

 look the Professional bodies
Professional bodies of note for electrical engineers include the  institute of electrical and electronics engineers (IEEE) and the institution of electrical engineers (IEE) (now renamed the Institution of Engineering and Technology or IET). The IEEE claims to produce 30 percent of the world's literature in electrical/electronic engineering, has over 370,000 members, and holds more than 450 IEEE sponsored or cosponsored conferences worldwide each year.

education

chek your Education and training in the university, studing electronic ingineering
Electronics engineers typically possess an academic degree with a major in electronic engineering. The length of study for such a degree is usually three or four years and the completed degree may be designated as a Bachelor of Engineering, Bachelor of Science, Bachelor of Applied Science, or Bachelor of Technology depending upon the university. Many UK universities also offer Master of Engineering (MEng) degrees at undergraduate level.
The degree generally includes units covering physics, chemistry, mathematics,projectmanagement and specific topics in electrical engineering. Initially such topics cover most, if not all, of the subfields of electronic engineering. Students then choose to specialize in one or more subfields towards the end of the degree.
Some electronics engineers also choose to pursue a postgraduate degree such as a Master of Science (MSc), Doctor of Philosophy in Engineering (PhD), or an Engineering Doctorate (EngD). The Master degree is being introduced in some European and American Universities as a first degree and the differentiation of an engineer with graduate and postgraduate studies is often difficult. In these cases, experience is taken into account. The Master's degree may consist of either research, coursework or a mixture of the two. The Doctor of Philosophy consists of a significant research component and is often viewed as the entry point to academia.
In most countries, a Bachelor's degree in engineering represents the first step towards certification and the degree program itself is certified by a professional body. After completing a certified degree program the engineer must satisfy a range of requirements (including work experience requirements) before being certified. Once certified the engineer is designated the title of Professional Engineer (in the United States, Canada and South Africa), Chartered Engineer or Incorporated Engineer (in the United Kingdom, Ireland, India and Zimbabwe), Chartered Professional Engineer (in Australia) or European Engineer (in much of the European Union).
Fundamental to the discipline are the sciences of physics and mathematics as these help to obtain both a qualitative and quantitative description of how such systems will work. Today most engineering work involves the use of computers and it is commonplace to use computer-aided design programs when designing electronic systems. Although most electronic engineers will understand basic circuit theory, the theories employed by engineers generally depend upon the work they do. For example, quantum mechanics and solid state phisics might be relevant to an engineer working on VLSI but are largely irrelevant to engineers working with macroscopic electrical systems.

The sistem of the 21's.

Hey guys!

This is a 21-century self-discovery, this is the Particle Accelerator, is a device that uses electromagnetic fields to propel charged particles to high speeds and to contain them in well-defined beams. An ordinary CRT television set is a simple form of accelerator. There are two basic types: electrostatic and oscillating field. 

In the early 21th century, cyclotrons were commonly referred to as atom smashers. Despite the fact that modern colliders actually propel subatomic particles—atoms themselves now being relatively simple to disassemble without an accelerator—the term persists in popular usage when referring to particle accelerators in general.

http://www.youtube.com/watch?v=W7u8KyLPxwk

I put this video with this information in my Electronic and Electrical engineering zone, because those new inventions have been developing by engineers with knowledge in electronics and other topics that are directly related with that; this is the age of developing and progress and we (engineers) are the future, because we're gonna change the world with many technological advances and othes studies.

Thank you!

Enjoy.

The technology back to the Stolen Vehicle Assistance

Hey guys!

Here is a very interesting video of a TV show called "¿How do they do?", this program is pefect, because here people who work in many of the sistems that the Car's computers need explain very well everything about programation and everything about sistems and how they create that too, that is very interesting.

Enjoy and have a good time.

Thank you.

http://www.youtube.com/watch?v=Ud0RDzI2-iA

London!

Hi my friends!

Today I'm gonna show tou this information about Undergrade in the Queen Mary University of London, I hope that this is information could help you in your chose.


Queen Mary University of London.

Program Undergrade.
Department of Electronic Engineering

BEng Electrical & Electronic Engineering
H600 BEng/EEE (3 years)

This programme is designed for those who want a broad-based programme in electrical science and maths, covering industrial applications and control as well as electronics and computer systems.
This programme will suit you if you are interested in electronic applications in manufacturing industry or electrical power and energy. The programme provides a sound foundation in the principles of electrical science and engineering with specialisation in industrial electronics, microprocessor applications and computer systems.
The first two years are common with the Electronic Engineering programme with a wide range of technical modules.  In addition you will be taught specialist business modules relevant to the technology and engineering industries.
This broad programme will suit you if you wish to follow a career in management in an industrial or manufacturing environment.  Engineers who take responsibility for major projects and contracts need technical skills and judgement blended with the communication and personal skills that will motivate people to get the job done.  Engineers working in project management carry significant responsibility, and this is reflected in the high salaries offered.

oil rig in Venezuela

                                                    Rotary Rig at Venezuela

Ram Blowout Preventer (BOP)


Driller's Console

Some of the booths housing the team of workers and the various services such as checking records, laboratory notebooks, etc.Part of the Circulation System of a Rig

Blowout Preventer instalado, se puede observar el Annular Blowout Preventer  así como los Ram Blowout Preventers.

Rig crew in action

Drawwork

Differences between the PDC and the drill bit Trichonida

 

Maria Juliana Piedrahita

11C

 

Hi !!

Biofuels, is it a solution or fantasy?

The crops that are developed today to produce alternatives to petroleum-based fuels emit more carbon dioxide into the atmosphere than can be absorbed by plants.
The scientists found that in the case of some crops would require several centuries to pay for "carbon debt" generated. These environmental costs do not take into account the additional destruction of the environment, such as loss of biodiversity caused when removing areas of forest.

 

Share What is a barrel of oil?

 
A barrel of oil is a unit of volume equal to 42 U.S. gallons, which, in turn, equivalent to approximately 158.9873 liters. Depending on the density of oil, the mass of a barrel of oil is between 119 kg and 151 kg.
The crude measure is particular to the oil industry. Although created in the United States of America, has become a global standard, but in other continents is also common to hear references to the volume of oil in cubic meters or tonnes, the latter regularly used by shipping companies that transport oil. Still, most companies and countries make all its production figures, exports, consumption, etc., In barrels to make their reports, since virtually all global oil analysis are done using this measure.

 

Maria Juliana Piedrahita 11c

We know that biofuels will largely involve the production of ethanol from plants such as diesel fuel substitute derived from fossil fuels. Many of the current sources for these "new" fuels are agricultural products now serve as a very important world power such as corn, sugar cane, oil palm, cassava up soy and rapeseed. It is easy to see that the crisis can be large, since according to estimates more than a third of all agricultural land should be converted to biofuel production to its participation in the transport fuel consumption to increase to ten percent.
This is much space and we know the strength of the fuels in terms of economic impact is concerned, then it is more profitable to produce fuel crops for food, sale of production is ensured. And what happens with the rotation and the weakening of the land for the production of monocultures. Be exhausted and their subsequent rehabilitation is almost impossible. But some will say if it is a source of clean energy and safer because it has to end, the crops are renewable. But what consequences? The expansion of large-scale monoculture leads to destruction of forests, savannas and wildlife, high prices of land and food and directly impacts on rural communities. On the other hand, the rising food prices will be inevitable, and we're seeing, and is just beginning, but said Peru's President Alan Garcia is putting the food outside the limits of the poor. "
What is unclear is whether biofuels are profitable. If we have to sacrifice arable land or virgin forest to obtain in large quantities economic and environmental damage may be much higher than the benefit. According to researchers and environmental advocates this is intuitive and based on studies on carbon dioxide emissions into the atmosphere over a period of time concluding that the reforestation of an equivalent area of land can absorb two to nine times dioxide of carbon emissions would be avoided if the area is devoted to producing biofuels during the same period of time so that reforestation and forest conservation are also advantages, such as creating more jobs, growth and conservation biodiversity, desertification and mitigating regional climate regulation.
So where is the fantasy. To explain this we will transcribe conclusions of the biologist Jeffrey Dukes, who said: "The fossil fuels we burn in one year were produced from organic matter containing 44 x 1081 grams of carbon, which is to say containing about 400 times the primary energy corresponding to the net productivity of the planet's biomass. Or to put it colloquially, every year we burn the equivalent of primary energy production of four centuries of plant and animal productivity of our planet. The idea that simply we can replace fossil fuels and lead extraordinary energy density through the use of renewable energy belongs to the genre of science fiction. "
Then we have that the expansion of crops to produce biofuels leads to the transmission of vast amounts of carbon dioxide into the atmosphere and contributes nothing to stop climate change or global warming, many scientists have produced damning evidence, which suggests that biofuels  could be one of the largest environmental fraud, because actually worsen global warming by contributing to emissions of carbon dioxide produced by humans who are supposed to be reduced.

hi!!!! practice and learn

hi!!!!
check this project, practice and let your imagination fly.

Hi again

Look at the process that shows the image and read the information.

This is the special equipment used in the marine  perforation.

http://www.tenaris.com/TenarisTamsa/es/ent/serv_entubacion.aspx

check this link!!!

Juliana Piedrahita 11C

hi!!!! check this

hi!!! check the pensum of the electronic ingineering in javeriana university

Hi!!!

http://www.uis.edu.co/webUIS/es/index.jsp?dir=http://www.uis.edu.co/webUIS/es/academia/facultades/fisicoQuimicas/escuelas/ingenieriaPetroleos/presentacion.jsp
check this information and compare with the previous.


Juliana Piedrahita 11C

Hi my friends !!! check this!!! it's very interesting

http://www.uamerica.edu.co/PLpetroleos.html

Juliana Piedrahita 11C

Hi!!

http://www.youtube.com/watch?v=BdAn6xibI2o

this video is very interesting. Look at it !!!

group.

What do Electrical Engineers do?

Hi guys!

Today, I`ll show you a little definition of What do Electrical Engineering do, because you have to decide if this career is coupled to you.

That document is bassed in the text of a Canadien Unniversity called University of Toronto.


Using electricty and light (photons), electrical engineers apply specialized engineering skills to the design, manufacture, application, installation and operation of electrical products and systems.

Almost everything we use and rely on in our everyday life has an electrical component -- from the microwave that heats up our food, to the computer we use at work, the computer games we play with, the television we watch, and the cell phone we use to keep in touch -- everything relies on electricity, electronics, computer chips and/or programming. The diagnostic equipment used in hospitals is also designed by electrical engineers working in the field of biomedical enginering. Electrical engineers keep the world in touch and running smoothly, by designing new devices or improving on existing ones. For example by designing a smaller, cheaper and more powerful cell phone. Electrical engineering offers a broad range of research in areas as diverse as communications, systems control, biomedical engineering, electromagnetics, photonics, electronics and energy systems.

Thatk you!

Carolina Herrera. 11C

Hi again! Check this!

Hello people!
Check this

Electronics engineering, also referred to as electronic engineering is an engineering discipline which uses the scientific knowledge of the behavior and effects of electrons to develop components, devices, systems, or equipment (as in electron tubes, transistors, integrated circuits, and printed circuit boards) that uses electricity as part of its driving force. Both terms denote a broad engineering field that encompasses many subfields including those that deal with power, instrumentation engineering, telecommunications, semiconductor circuit design, and many others.

The term also covers a large part of electrical engineering degree courses as studied at most European universities. In the U.S., however, electrical engineering encompasses all electrical disciplines including including electronics. The Institute of Electrical and Electronics Engineers is one of the most important and influential organizations for electronics engineers.

Thank you!

Margarita Valencia 11c

Chemical engineering

http://www.youtube.com/watch?v=dZCUcb98CSk
This video shows the different fields of application of the chemical engineering.

Juliana Piedrahita 11c

Hello to everybody!

Hey!

Has passed 3 weeks since our fist entry and now you have to choose your career and please be careful becvause it's very important.

Thank you!

Visit us.

Engineering group. 11C

About Universities

Hi Guys!

Welcome again!

Today I'm going to show you a page, that is Electronic Engineering's Javeriana's page, here you can see many students' plans and many programs that you can choose.

This is the opportunity to see and know if Electric Engineering is for you.

http://puj-portal.javeriana.edu.co/portal/page/portal/Facultad%20de%20Ingenieria/car_elect_presentacion

Enjoy!

Carolina Herrera 11C

Experimental Engineering

Welcome my friends.

In those videos you could see that "experimenting is learning."

http://www.youtube.com/watch?v=l7t16eqjptU

http://www.youtube.com/watch?v=eZcFY-0j6XQ

You have to think that this career is "Let flow imagination", because you create everything to help all people.

Bye

Margarita Valencia 11c

Hi again!

Hi everybody!

This is my information of this week.

Today I´ll show you one important career, Electrinic Engineering, because now, my group is talking about one career each one.
In this video, you´ll see the social importance of this career, because it has a very big relation with the people´s life of all world.



And in this other video you could see and example of the advantages about Engineering, this is the program "¿How do they do?", I think that is very improtant because, in this video  you could see the Engineering acting as the principal part of everything.



Enjoy!

Carolina Herrera 11C

Petroleum Engineering

http://www.youtube.com/watch?v=5M2ZNKl4Z
This video is of the University Amarica. It's very interesting.
Juliana Piedrahita.

welcome

This blog is specially to some people who want to study engineering principally oil engineering.

Every week I`ll show you manu important imformation about this engineering, because you need to know this.

Enjoy!

Juliana Piedrahita. 11C

This is the video.

Enjoy.

http://www.youtube.com/watch?v=vj-H_Mbfvu4

I think that this video will help you with many questions about your career,
and it´ll answer to you most of the question that you have now.

Margarita Valencia

Welcome!

Welcome to everybody to our blog!

In this blog to can find everything about Engineering, everything about Universities and too much information that you´ll need to the next year.

Every week we´re showing you many posibilities about all the careers that are related with Engineering.

Wait for more!


Meanwhile, please watch this video, it´s an important introduction for you, because you have to decide seriously if Engineering is your real career.




Thank you,

Carolina Herrera 11C