How magic work

Put circuits on a board.

Make holes on the board.

Put enough components.

A little bit of coding.

Fabric the casing.

There you go magic called electronic.

The ComeBack

Finally after a long vacant from getting my finger locked from typing here i am graduated as a degree holder.

Reaction:
Family: Later Master ok.
Friends: Congratulations... so you got a job? How much you get?
Relative: Wow.. so when you want to get married?
Cousin: Buat bungkus nasi lemak jela sijil. (Turn the certificate into 'nasi lemak' wrapper)

Me: -___________-"

Industrial visit to Canon Opto Sdn. Bhd. factory

a visit to Canon Opto Sdn. Bhd. factory in Shah Alam, Selangor on 6/12/12.

by student of SMJE 12/13 and not to forget the lecturers, (Mr. Ridzuan). we reached our destination, The Canon Opto factory in Shah Alam by 9 am. The journey to the factory didn't take a long time to reach as Shah Alam. here some pictures of the visit.

this is picture in the bus on our way to Shah Alam.

we reached there by 9a.m

first there were safety briefing by the staff of Canon Opto factory. 

in  picture below we were told by a staff on how Canon Opto on how they treat the factory waste.

here is the only En Redzuan.

the chemical solution area

they use the ioning machine for their solid waste to turn into charcoal 

the machine

the result

here is the liquid waste

then were given briefing again before going to the reassemble factory of the camera

 unfortunately, we are not allowed to take any picture in the reassemble hall..

the show us how the camera lens were made and be assembled to the camera.

here is the last gathered.

we were given souvenirs..

 lunch!

and we safely reached to KSJ at 2pm.. 

THANKS to Canon Opto and the lecturer..........

Thermal Imaging

Here's how thermal imaging works:

1. A special lens focuses the infrared light emitted by all of the objects in view.
2. The focused light is scanned by a phased array of infrared-detector elements. The detector elements create a very detailed temperature pattern called a thermogram. It only takes about one-thirtieth of a second for the detector array to obtain the temperature information to make the thermogram. This information is obtained from several thousand points in the field of view of the detector array.
3. The thermogram created by the detector elements is translated into electric impulses.
4. The impulses are sent to a signal-processing unit, a circuit board with a dedicated chip that translates the information from the elements into data for the display.
5. The signal-processing unit sends the information to the display, where it appears as various colors depending on the intensity of the infrared emission. The combination of all the impulses from all of the elements creates the image.

Types of Thermal Imaging Devices

Most thermal-imaging devices scan at a rate of 30 times per second. They can sense temperatures ranging from -4 degrees Fahrenheit (-20 degrees Celsius) to 3,600 F (2,000 C), and can normally detect changes in temperature of about 0.4 F (0.2 C).

There are two common types of thermal-imaging devices:

Un-cooled - This is the most common type of thermal-imaging device. The infrared-detector elements are contained in a unit that operates at room temperature. This type of system is completely quiet, activates immediately and has the battery built right in.

Cryogenically cooled - More expensive and more susceptible to damage from rugged use, these systems have the elements sealed inside a container that cools them to below 32 F (zero C). The advantage of such a system is the incredible resolution and sensitivity that result from cooling the elements. Cryogenically-cooled systems can "see" a difference as small as 0.2 F (0.1 C) from more than 1,000 ft (300 m) away, which is enough to tell if a person is holding a gun at that distance!

While thermal imaging is great for detecting people or working in near-absolute darkness, most night-vision equipment uses image-enhancement technology.

Reflective Journal 6 (20/11/2012)

Hye there,
   the entry for this time is about "Electronic System in Industry" speech, given by Mr Vivek Panicker from Titan Thermal Solutions Sdn Bhd.

This is a little bit about what he had given in his speech,

• Overview of Electronic Systems
• Role of Electronics in Industry
• Overview of Imaging Industry
• Electronics within Thermal Imaging Industry

This is a copy of his slide:

The overview of electronic system.

The role of electronic in industry.

The overview of imaging industry.

The electronics within thermal imaging industry

Formula that usually been used in electronic system

For the image concepts and terms

Pixels and resolutions

Pixels & Resolution

A digital image is formed by pixels, the smallest piece of information in an image. Often represented using dots, squares or rectangles. More pixels in an image, the sharper and clearer the image is.

Video & Frames

A digital stream of video is made of a group of pictures (frames) captured across a period of time. More frames per second, the lesser the smoother in the video.

Thermal imaging

Infrared thermography (IRT), thermal imaging, and thermal video are examples of infrared imaging science. Thermal imaging cameras detect radiation in the infrared range of the electromagnetic spectrum (roughly 9,000–14,000 nanometers or 9–14 µm) and produce images of that radiation, called thermograms. Since infrared radiation is emitted by all objects above absolute zero according to the black body radiation law, thermography makes it possible to see one's environment with or without visible illumination. The amount of radiation emitted by an object increases with temperature; therefore, thermography allows one to see variations in temperature. When viewed through a thermal imaging camera, warm objects stand out well against cooler backgrounds; humans and other warm-blooded animals become easily visible against the environment, day or night. As a result, thermography is particularly useful to military and other users of surveillance cameras.

Then after the speech,

once again Dr Kamal came and remind us about the poster assignment that he gave to us recently.

That all i can give about the class.

hope you enjoy.

now to prepare the poster.

canon opto (malaysia) (5th reflection)

Hye there,

 again this week we had presentation of electronic industry, from Mr. Muhammad Azlan Amran, the Senior General Manager of Canon Opto (Malaysia) Sdn Bhd.

Here is a litte bit about him,
he was a student of University Malaya (1984-1986) and went to Japan.
He used to work in NTT (Nippon Telegram and Telephone Corporation).
Lastly he work in Canon Malaysia from march 1990 till now.

Now about his work place,

Canon Opto (M) Sdn Bhd is one of the Japanese branch company that located in Shah Alam.
This company description is Manufacture of Optical Instrument and Equipment (SSM).

Now is what he had give to us..
he gives us a lot of description on Canon's camera, how the lens are made, and much more.
Then he give us about how Japanese culture in doing their work.

first he let us know about EQCD, that is


E (environment) - The product manufactured must not contribute to the nature pollution such as 
                               air, water or others.
Q (quality) - Canon company has their own quality
C (cost)     - Every company that produce a product wanted a low-cast product to get a reasonable 
                    price for their customers.
D (delivery) - The work must be done on time.


He even tell us about Japanese culture that based on: 

 "HORENSO"  
HOU - Houkoku which means report, report must be done as simple as possible, it       
           is important to give the report and start with conclusion.
REN - Renraku which means contact. It is about what, when, where, and who. 
SOU - Soudan means consultation, when we have problems, we can consult anyone or do the                 
           appointment and inform the issue/themes/problems.

"SAN-GEN" (3 GEN)        
        GENBA : Site, actual spot
        GENBUTSU : Actual thing
        GENJITSU : Reality


It is an interesting culture to be follow by us in Malaysia
Only it depends on us either to follow it or not.
That is all i get from that day.
Hope to see you again..
sayonara..

Shinya Yamanaka

Had you heard of this name?

well if are studying in bio-electronic you should know him..

He is Shinya Yamanaka that were awarded the Nobel prize for Physiology and Medicine along with John Gurdon.

here is a bit about him

Shinya Yamanaka

Born: 1962, Osaka, Japan

Affiliation at the time of the award: Kyoto University, Kyoto, Japan, Gladstone Institutes, San Francisco, CA, USA

Prize motivation: "for the discovery that mature cells can be reprogrammed to become pluripotent"

More about Dr. Yamanaka

Dr. Shinya Yamanaka is a Senior Investigator and the L.K. Whittier Foundation Investigator in Stem Cell Biology at the Gladstone Institutes. At Gladstone, he conducts research at the Roddenberry Stem Cell Center. Dr. Yamanaka is also a Professor of Anatomy at the University of California, San Francisco, as well as the Director of the Center for iPS Cell Research and Application (CiRA) and a Principal Investigator at the Institute for Integrated Cell-Material Sciences, both at Kyoto University.

In 2012, Dr. Yamanaka was awarded the Nobel Prize in Physiology or Medicine for his discovery that adult somatic cells can be reprogrammed into pluripotent cells. By introducing the genes for four factors that turn genes on and off, he induced the skin cells of adult mice to become like embryonic stem cells, which he called induced pluripotent stem (iPS) cells. This iPS cell technology represents an entirely new platform for fundamental studies of developmental biology. Rather than using disease models made in yeast, flies, mice or other animals, iPS cells can be taken from patients with a specific disease. As a result, they contain a complete set of the genes that resulted in that disease—representing the potential of an almost perfect disease model for studying disease development, new drugs and treatments.

Dr. Yamanaka’s current research focuses on ways to generate cells resembling embryonic stem cells by reprogramming somatic, or skin, cells. He seeks to understand the molecular mechanisms that underlie pluripotency and the rapid proliferation of embryonic stem cells—they can become any type of cell in the body—and to identify the factors that induce reprogramming.

In 1996, Dr. Yamanaka became an Assistant Professor at Osaka City University Medical School. In 1999, he was appointed Associate Professor at Nara Institute of Science and Technology, where he became a full professor in 2003. He took his current position as a professor at Kyoto University in 2004 and was appointed as a Senior Investigator at the Gladstone Institutes in 2007. Since 2008, he has directed CiRA.
In addition to the Nobel Prize, Dr. Yamanaka has received many awards and honors, including the Albert Lasker Basic Medical Research Award, the Wolf Prize in Medicine, the Millennium Technology Award, the Shaw Prize, the Kyoto Prize for Advanced Technology, the Gairdner International Award, the Robert Koch Award and the March of Dimes Prize.

Dr. Yamanaka earned an MD from Kobe University in 1987 and a PhD from Osaka City University in 1993. From 1987 to 1989, he was a resident at the National Osaka Hospital. From 1993 to 1996, he was a postdoctoral fellow at Gladstone.

Based on the above..
we can admire him on how he achieve his success on his field..
for more information
http://www.cira.kyoto-u.ac.jp/e/index.html
http://www.icems.kyoto-u.ac.jp/e/ppl/grp/yamanaka.html