Emerging Technologies in [nuclear] Instrumentation and Controls

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Through extensive research, the Government of Canada and other national and international agencies have identified and validated nine essential skills. These skills are used in nearly every occupation and throughout daily life in different ways. A series of CCDA -endorsed tools have been developed to support apprentices in their training and to be better prepared for a career in the trades. The tools can be used independently or with the assistance of a tradesperson, trainer, employer, teacher or mentor to:. Tools are available online or for order. The application of these skills may be described throughout this document within the competency statements which support each subtask of the trade.

The following are summaries of the requirements in each of the essential skills, taken from the essential skills profile. Here is a link to the complete essential skills profile. Instrumentation and control technicians require reading skills to locate and interpret technical information for their trade.

These texts include technical articles about new products and industry practices, bulletins from manufacturers and on health and safety, calibration and service guides, incident reports, procedures, manuals and notes. Instrumentation and control technicians locate and interpret information in both print and electronic formats. Types of documents referenced include computer printouts with numeric information, supplier catalogue listings and engineering documentation such as forms, graphs, tables, charts, schematics, assembly diagrams and drawings.

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They may also create documents such as on-site sketches and detailed schematics, assembly drawings, graphs and charts. Writing skills are used by instrumentation and control technicians to create parts lists, maintenance schedules, and inspection reports. Instrumentation and control technicians write procedures for the control and operation of equipment and to troubleshoot faults. They use writing skills when communicating through e-mail and providing status updates in logbooks.

Instrumentation and control technicians must apply measurement and calculation, data analysis and numerical estimation skills to their tasks. Some of these tasks include measuring analyzer malfunctions, calculating flow, calculating volume displacement, monitoring pressure, interpreting deviations on graphs, and comparing values and measurements. Instrumentation and control technicians evaluate sets of data collected from tests and simulations to troubleshoot faults, assess equipment performance and assess the progress of wear.

They may also discuss systems design and problems with supervisors and engineers, and provide expert advice and opinion. Instrumentation and control technicians also exchange technical repair and troubleshooting information and speak to process operators about equipment and machinery breakdown. At times, they may make formal presentations to explain monitoring procedures or new equipment.

Instrumentation and control technicians troubleshoot malfunctions, take corrective measures to avoid potential hazards and decide whether to repair or replace components based on time and cost factors. They plan and organize maintenance schedules, the installation of new machinery and the tradespeople assigned to install the machinery.

Instrumentation and control technicians must be able to think quickly and synthesize the information at hand to deal with emergencies such as serious equipment malfunctions that could cause injury, or property and environmental damage. They may use hand held digital devices to configure settings and to access data such as measurement and operational values.

Students in this program may have the opportunity to apply to paid summer co-ops. The co-op runs during the summer between years one and two. This co-op allows you to build on your academic education, experience the work environment and make valuable contacts in one of the many diverse industries requiring instrumentation technician professionals.

The co-op is optional and securing a position is the responsibility of the student. The number of Fleming-provided job leads fluctuates from year to year.

B.Tech. Instrumentation & Control

Instrumentation Technician graduates use a variety of computing, electromechanical, and test equipment to install, troubleshoot, calibrate, maintain, and repair simple or complex measurement and control devices in a variety of fields. Opportunities for employment in this field are expected to increase due to retirements, and to recent growth in the manufacturing sector. With just 8 additional courses you can complete a second diploma at Fleming in the Electrical Engineering Technician program and graduate with 2 diplomas in 3 years.

Students applying to Instrumentation and Control Engineering Technician must meet the following requirements:. Grade 12 C courses will be accepted where Gr 11 C course requirements are listed. Where College level courses are listed, U and M courses will be accepted. Two Gr 11 courses will be accepted in lieu of a Gr 12 course requirement.

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If you are 19 years of age or older before classes start, and you do not possess an OSSD, you can write the Canadian Adult Achievement Test to assess your eligibility for admission. Additional testing or academic upgrading may be necessary to meet specific course requirements for this program.

CBC Nuclear Technology Program - Arturo

You may be able to use credits obtained at Fleming College to continue your postsecondary education in pursuit of a degree. The articulation and credit transfer agreements with our partner institutions are summarized below. To apply please see the KOM Consultants website. This includes all aspects of this area of remote sensing technology including in particular:. The desire of the MRWG members is to use this website as a place to both provide information to the community on these topics as well as gathering input from the community as a whole.

This includes offering members of the general remote sensing community the opportunity to highlight relevant developments. This also includes the compilation of white papers summarizing the views of the MRWG members in these areas.

To that end, the MRWG has identified the following key trends and issues within the passive microwave remote sensing field:. The desire for on-board digital signal processing is pushing the passive microwave field towards the use of digital radiometry. This includes digital spectrometers for the detection and removal of RFI and for sounding trace gases in the Earth and in planetary atmospheres, and digital correlators for use in the digital beam forming and in polarimetric radiometry. These applications require low mass, low power, and high-performance digital solutions that can operate in high radiation environments.

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In the future, this web page will include white papers addressing the key developments in the above areas. Additional information in these specific areas as well as any other relevant area, including specific developments from members of the general community, is welcomed and encouraged. Any input can be sent via email to the WG leads. At a later time, a discussion forum will be opened, which can also be used to communicate this information. With a number of instruments already operational or pending launch within the coming years, many of their original technological issues have been resolved, still the long term reliability of key active components and the survival on harsh space environment requires additional efforts and investments.

These areas are not restrictive in any way and additional topics may be pursued based on community inputs. Furthermore, the generic goal of instrument flexibility and multi-functionality is gaining momentum in this WG with the broadening of active optical applications optical telecom, navigation etc. In the future, this web page shall include white papers addressing the key developments in the above mentioned topics. Feel free to provide any input via email to the WG leads to include additional topics for consideration. With the steady increase in sources of GNSS signals over the coming years, these two techniques are also set to increase in their use and understanding.

The working group will therefore act as a forum for exchange and possible cooperation in these fields with respect to the instrument designs, processing and interpretation of results.

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On the one hand occultation is already established as an Earth Observation instrument e. For both, the increase in numbers of navigation systems GPS, Galileo, Glonass, Beidou , numbers of satellites, numbers of different frequencies including possible extension into other bands such as C-band , increase of power transmitted and increase of bandwidth, will all add to the capabilities required of future GNSS instruments. These developments in GNSS can be of great benefit to the remote sensing community since they will not only allow far higher coverage than can currently be achieved with GPS alone, but also improved signal quality and hence enhancing the quality remotely of the remotely the technology for future instruments.

For instance, for certain applications, e. At the same time, the beam patterns must not only be agile but also well known and very stable, placing significant demands on the antenna design and the beam forming network behind it.

Another point is that the raw data rate for all these signal sources is extremely high necessitating on-board processing by which very significant data rate reductions can be realized. As the use of GNSS signals for remote sensing gains acceptance in the various scientific user communities, demands on the instrument are very likely to change as are the ways of processing and interpreting the data.

In the past, the preferred architecture for most spaceborne Earth remote sensing missions was a single large spacecraft platform containing a sophisticated suite of instruments. Following the evolution of the computer from room-sized to pocket-sized, technology has paved the way for a similar shift in satellites. First, small satellites allow for cheap access to space. By flying as secondary payloads and utilizing excess capacity, launch costs can be reduced by an order of magnitude or more.