Tuesday, 31 January 2012

CNY~2012~~

hehehe~show some childish friend d photo bah~~XP

hehehe~lz~left u nia o~~come sama sama childish bahXDD

Monday, 23 January 2012

哟!新年到了!!

嘿嘿嘿～今年的新年在SIBU过! 诶诶诶诶诶诶～我才知道原来4四点就吃团圆饭很正常?!话说回来...前年是几点吃的我也忘记了～哈哈哈~老了记忆力就是不好~~XP 话就不多说～来看看图片吧~~

哈哈哈～新年到了我家的冰箱就只穷得剩下汽水而已XD

我家的零食～～～其实没什么东西好吃~~~

哈哈哈～幼稚的sdo妹在玩烟花~大家也来我家玩吧XD

哎哟哟～这张更惨～他们竟然在玩pop pop~~shhhh...其实我也有玩啦...

大年初一我没就在自己家拜年了~~~

hahaha~这个妹也是~~

还在挑还在挑XD

来张合照XD

2nd camera><!!

我没竟然还去giant买个不倒翁回来XD

我爸跟他朋友一定是继remix过后最会38的男人><

可爱的糖><

吃太多了！罚扫地XD

回民都鲁的前一刻~~

完

Friday, 20 January 2012

阿勒～～～～～～～～早上醒来妈妈才说屋子还没整理好明天早上才去?! 怎么这样啊~~~~~~~~人家都跟朋友们说今天去了说~~~可怜的我又要帮忙整理屋子~整理房间时才发现我房间有够乱的>< 妹妹的衣服都丢在我衣橱里面>.<而用过的参考书竟然比山还要高...整个傻眼去~~呵呵呵~前天250从plkn回来了呢～(虽然是回来过年而已)看过去成熟不少也认识了很多新朋友~果然人还是要出去闯一闯呢!pia~唉~突然觉得自己在新的一年没什么改变....还是那么幼稚不能自己一个人独立~总是让自己想太多, 总是无谓的猜测别人的想法~其实人家根本就不是那么想的~真希望回到那件事还没发生的时候~那时候的我才不会质疑朋友对我的想法,就算不是经常在一起聊天也不会觉得尴尬,也不会像现在那么自私...我的新年新希望就是成熟一点!不要生病!学习独立!2012年了～我不要像以前一样什么都不做只坐在那里等着别人帮我打算好一切!

完

哎呀呀～大扫除·累!

hohohohoho~~(<<大扫除还那么开心~疯了XD) 哎呀呀～明天就要出门去了neh~~今天要大扫除整理好所有东西才出门去~我很厉害下咯～边装零食边拜年~边装肉干边sapu～哈哈哈哈哈～结果被妈妈念了一顿~爸爸今天也没去做工在家里油漆~虽然我觉得差啦XD 还有把以前穿过不要的鞋子整理掉～擦窗口之类的~之后还到处去送货~送东西去给妈妈的朋友~~还在人家家先拜了一次年XD后来妈妈的朋友给了一tin类似面还是什么的东西～总觉得味道似曾相识啊~~

就是这个东西liao~

希望新年快点到来~~

完

Wednesday, 18 January 2012

耶耶!!要过新年咯!!

恭喜贺恭喜恭喜你呀~恭喜恭喜恭喜你~~祝大家新年快乐万事如意红包拿来XDD 新年还没到我妹就已经自己放假了咯～给她冷到～哎呀呀～土曜日就要出门去了～想到要出门就觉得很累啊~可是去了就会有很多红包拿~哈哈哈哈~今年没买什么衣服～因为我不喜欢去买衣服~鞋子也是乱乱买的～嘿嘿嘿～真希望快点回来跟大家一起去团拜~~ ♡ 大家一定要来我家拜年哦

既然新年要到了...

送大家两只招财猫～俗语说"家有阿花一定旺一定发!" XD

哈哈哈哈哈～每次在电视上看到这种图片都会有一个声音......"Hai-yo!"

在此还要唱衰樱桃小丸子叻～嘿嘿嘿～她是个hentai来的～也是hendai～哈哈哈～有时又呆呆地～我也是感动+高兴下～没想到既然会有人偷偷地默默的在看我们写的blog～我之前都以为写了没人看～aisteru yo～～～～～～～～～～hahahahahaXD

Tuesday, 17 January 2012

第六篇: What is Biotechnology?

What is Biotechnology?

Biotechnology in one form or another has flourished since prehistoric times. When the first human beings realized that they could plant their own crops and breed their own animals, they learned to use biotechnology. The discovery that fruit juices fermented into wine, or that milk could be converted into cheese or yogurt, or that beer could be made by fermenting solutions of malt and hops began the study of biotechnology. When the first bakers found that they could make a soft, spongy bread rather than a firm, thin cracker, they were acting as fledgling biotechnologists. The first animal breeders, realizing that different physical traits could be either magnified or lost by mating appropriate pairs of animals, engaged in the manipulations of biotechnology.
What then is biotechnology? The term brings to mind many different things. Some think of developing new types of animals. Others dream of almost unlimited sources of human therapeutic drugs. Still others envision the possibility of growing crops that are more nutritious and naturally pest-resistant to feed a rapidly growing world population. This question elicits almost as many first-thought responses as there are people to whom the question can be posed.
In its purest form, the term "biotechnology" refers to the use of living organisms or their products to modify human health and the human environment. Prehistoric biotechnologists did this as they used yeast cells to raise bread dough and to ferment alcoholic beverages, and bacterial cells to make cheeses and yogurts and as they bred their strong, productive animals to make even stronger and more productive offspring.

Throughout human history, we have learned a great deal about the different organisms that our ancestors used so effectively. The marked increase in our understanding of these organisms and their cell products gains us the ability to control the many functions of various cells and organisms. Using the techniques of gene splicing and recombinant DNA technology, we can now actually combine the genetic elements of two or more living cells. Functioning lengths of DNA can be taken from one organism and placed into the cells of another organism. As a result, for example, we can cause bacterial cells to produce human molecules. Cows can produce more milk for the same amount of feed. And we can synthesize therapeutic molecules that have never before existed.

第五篇: What is Petroleum Engineering?

Petroleum engineering is a branch of engineering that revolves around the extraction of hydrocarbons, in the form of crude oil or natural gas. Therefore, petroleum engineers are involved in nearly every step of the oil and gas field evaluation, development and production.

Petroleum engineers typically specialise as:

Petroleum geologists
Petroleum geologists utilise geological and geophysical methods to locate hydrocarbons.
Reservoir engineers
Reservoir engineers optimise the production of oil and gas by putting into ensuring proper well positioning and by overseeing production levels.
Production engineers
Production engineers are the middle men between the reservoir and the well. They manage the interface between the two by using specialised equipment and techniques.
Drilling engineers
Drilling engineers work in teams made up of other engineers, scientists and contractors to manage the more technical aspects of drilling.

What does a Petroleum Engineer Do?

Producing oil and gas and other resources from the earth is the primary challenge of the petroleum engineer. Petroleum now provides over 70% of the world’s energy and is likely to do so for at least another 50, and probably 100, years. In a sense, no other branch of engineering is more concerned with our everyday lives. Economic and environmentally safe production of petroleum resources requires creative application of a wide spectrum of knowledge, ranging from the basic sciences of mathematics, physics, geology, and chemistry to almost all engineering disciplines (mechanical, chemical, electrical, etc.).

The petroleum engineer evaluates potential oil and gas reservoirs, oversees drilling activities, selects and implements recovery schemes, and designs surface collection and treatment facilities. The petroleum engineer increasingly uses advanced computers in this work, not only in analysis of exploration data and simulation of reservoir behavior, but also in automation of oilfield production and drilling operations. Petroleum companies own many of the world’s supercomputers.

Petroleum engineers have a future full of challenges and opportunities. They must develop and apply new technology to recover hydrocarbons from oil shale, tar sands, and offshore oil and gas fields. They must also devise new techniques to recover oil left in the ground after application of conventional producing techniques. Example of these “enhanced” recovery methods are steam injection, underground combustion, and injection of chemically treated water to release oil trapped in the pores of rock. These new methods are aimed at recovering additional petroleum from known reservoirs, beyond the 25% typically recovered with conventional technology.

Techniques developed for the recovery of petroleum will increasingly be applied to the extraction of other important minerals as in-situ uranium leaching, geothermal energy production, and coal gasification. Petroleum engineers are also able to contribute to such non-energy activities as pollutant remediation, underground waste disposal and hydrology.

Since many petroleum companies conduct worldwide operations, the petroleum engineer may have the opportunity for assignments all over the world. Petroleum engineers must solve the variety of technological, political, and economic problems encountered in these assignments. These exciting technological challenges combine to offer the petroleum engineer a most rewarding career.

第四篇: What is Electrical and Electronic Engineering

What is it all about?
Electrical and Electronic Engineering is an exciting and dynamic field. Electrical engineers are responsible for the generation, transfer and conversion of electrical power, while electronic engineers are concerned with the transfer of information using radio waves, the design of electronic circuits, the design of computer systems and the development of control systems such as aircraft autopilots. These sought-after engineers can look forward to a rewarding and respected career.

香草咖啡: 辐射must b vry high~

What we do about it
Electrical energy systems - encompass the study and design of electrical transmission systems, electrical machines and variable speed drives; high power electronic converters and high voltage engineering. This requires engineering on a grand scale, such as power distribution across Southern Africa. Power generation from renewable resources, such as wind and sun, and electrical transport, such as battery electrical vehicles, are of growing importance in the electrical engineering field and postgraduate studies.
Electronics - the study of components and circuits used to construct items such as audio amplifiers, radio transmitters and computer circuits. Students learn about elementary electrical components, transistors, integrated circuits, computer circuitry and power electronics. The field specialises in areas such as microwave electronics, superconducting electronics, ultra-high speed electronics and the prevention of electromagnetic interference between devices.
Electromagnetic systems - are diverse and complex, ranging from the study of the electromagnetic effects of motors and electrical insulators to radio and radar antennas, radio waves and visible light (fibre optics). The scope of study ranges from undergraduate introductory courses to world class research at graduate level.
Computer systems - students are trained to design and implement computers and digital electronic systems. This field also covers the design and construction of microcomputers built to control almost every electrical appliance, from automatic irrigation systems to autopilots for aircraft. Computer programming for embedded systems and reconfigurable logic circuits and the use and development of real time operating systems to address a variety of engineering problems, are also of key importance.
Control systems - range from the temperature control in air conditioning systems to the sophisticated automatic landing systems that allow aircraft to land autonomously in thick fog or to point camera systems accurately from satellites to target areas on the ground. Students learn techniques to design control systems for both electronic (analogue) and computer (digital) implementations and also to apply the knowledge in other branches of engineering.
Signal processing - Speech, radio waves and television images are all examples of signals. Students study the behaviour of these signals and apply computers usefully to process them (eg speech, speaker and image recognition, software defined radios and protocols). Mathematical aids are created to analyze and understand these signals. Postgraduate students are involved with leading edge research in speech processing, radar and sonar, image processing, software defined radios and protocols/networks.

第三篇: What is Civil Engineering?

Engineering is a term applied to the profession in which a knowledge of the mathematical and natural sciences, gained by study, experience, and practice, is applied to the efficient use of the materials and forces of nature. Engineers are the ones who have received professional training in pure and applied science.Before the middle of the 18th century, large-scale construction work was usually placed in the hands of military engineers. Military engineering involved such work as the preparation of topographical maps, the location, design, and construction of roads and bridges; and the building of forts and docks; see Military Engineering below. In the 18th century, however, the term civil engineering came into use to describe engineering work that was performed by civilians for nonmilitary purposes.

Civil engineering is the broadest of the engineering fields. Civil engineering focuses on the infrastructure of the world which include Water works, Sewers, Dams, Power Plants, Transmission Towers/Lines, Railroads, Highways, Bridges, Tunnels, Irrigation Canals, River Navigation, Shipping Canals, Traffic Control, Mass Transit, Airport Runways, Terminals, Industrial Plant Buildings, Skyscrapers, etc. Among the important subdivisions of the field are construction engineering, irrigation engineering, transportation engineering, soils and foundation engineering, geodetic engineering, hydraulic engineering, and coastal and ocean engineering.

Civil engineers build the world’s infrastructure. In doing so, they quietly shape the history of nations around the world. Most people can not imagine life without the many contributions of civil engineers to the public’s health, safety and standard of living. Only by exploring civil engineering’s influence in shaping the world we know today, can we creatively envision the progress of our tomorrows.

香草咖啡: hahaha~next time can 理直气壮d say "这条马路是我做的!!"

第二篇: What is Mechanical Engineering?

Mechanical engineers design and develop everything you think of as a machine - from supersonic fighter jets to bicycles to toasters. And they influence the design of other products as well - shoes, light bulbs and even doors. Many mechanical engineers specialize in areas such as manufacturing, robotics, automotive/transportation and air conditioning. Others cross over into other disciplines, working on everything from artificial organs to the expanding field of nanotechnology. And some use their mechanical engineering degree as preparation for the practice of medicine and law. The mechanical engineer may design a component, a machine, a system or a process. Mechanical engineers will analyze their design using the principles of motion, energy, and force to insure the product functions safely, efficiently, reliably, and can be manufactured at a competitive cost.

Mechanical engineers work in the automotive, aerospace, chemical, computer, communication, paper, and power generation industries. Mechanical engineers will be found in virtually any manufacturing industry. Increasingly, mechanical engineers are needed in the environmental and bio-medical fields. Indeed virtually every product or service in modern life has probably been touched in some way by a mechanical engineer.

What do Mechanical Engineers do?

This Senior Design Team won 2nd place in the Undergrad Research Expo. They developed an automatically Indexing Insert Toolholder design project that focused on the design, prototyping, and testing of a toolholder for turning operations. The key feature that separates this toolholder from others on the market is its ability to automatically rotate an indexable insert from a dull to fresh edge via an electrically actuated mechanism. Doing so saves significant machining downtime associated with the current method of manually indexing an insert. The projected savings in time allow the end user to reduce the costs related to machining parts, especially if the components being turned are made from hard materials that wear the insert rapidly.

Up-Sized Tractor Variant Prototype: Elmer’s Crane & Dozer was formed in 1956. They currently have 15 locations in Michigan’s Lower Peninsula. They have built 20 current Du-More tractor models. The current Du-More has a 1.5 yard bucket and 115 HP engine. Our team is designing a larger, more powerful and more capable tractor for Elmer’s Crane and Dozer, based on the current Du-More model. The new machine will incorporate existing components while preserving the functions of the existing model.

香草咖啡: about robotics? OMG...me 笨手笨脚 d~cannot lar...

第一篇: What Is Chemical Engineering?

Chemical engineering basically is applied chemistry. It is the branch of engineering concerned with the design, construction, and operation of machines and plants that perform chemical reactions to solve practical problems or make useful products. Like all engineers, chemical engineers use math, physics, and economics to solve technical problems. The difference between chemical engineers and other types of engineers is that they apply a knowledge of chemistry in addition to other engineering disciplines. Chemical engineers sometimes are called 'universal engineers' because their scientific and technical mastery is so broad.

香草咖啡: erm erm...universal engineering a...looks like very difficult to study neh...

What Do Chemical Engineers Do?

Some chemical engineers make designs and invent new processes. Some construct instruments and facilities. Some plan and operate facilities. Chemical engineers have helped develop atomic science, polymers, paper, dyes, drugs, plastics, fertilizers, foods, petrochemicals... pretty much everything. They devise ways to make products from raw materials and ways to convert one material into another useful form. Chemical engineers can make processes more cost effective or more environmentally friendly or more efficient. As you can see, a chemical engineer can find a niche in any scientific or engineering field.

给未来的自己~~

唉唉唉～～从今天起要一一了解各种大学可以选修的科目～好让未来的自己能找到自己喜欢的工作~~ 大家也可以作为参考～一起来了解看看吧～

Monday, 16 January 2012

宠物情人シ

国家/地区： 韩国
类型： 爱情 / 剧情 / 喜剧
片长：110分钟
分级： South Korea:12
对白语言： 韩语
发行公司： Lotte Entertainment
官方网站： http:// www.urpet2011.co.kr
宠物情人 - 剧情
影片改编自日本同名漫画，韩国影视圈早已对这个姐弟恋的故事虎视眈眈，而凭借《原来是美男》成为亚洲红星的张根硕也通过本片再度验证自己的人气。
宠物情人 - 幕后花絮
·影片大部分外景戏选定在日本茨城县各地拍摄。开机前，剧组在茨城机场召开了制作发布会，现场云集了三千余名日本粉丝，为男女主角捧场。
·韩国人气乐队组合FTisland队长崔钟勋在本片中首次触电，扮演女主人公的弟弟。