Physics SPM 2011

Hi Physics Guys and Gals

Welcome to my new blog.

SPM and STPM Papers

STPM Physics Papers : Click Here
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SPM PHYSICS Papers
MRSM Physics Paper 1 2009
MRSM Physics Paper 2 2009
MRSM Physics Paper 3 2009

Kedah Trial Physics Paper 1 2009
Kedah Trial Physics Paper 2 2009
Kedah Trial Physics Paper 3 2009
Kedah Trial Physics Scheme 2009
Kedah Trial Physics P2 P3 Answers 2009

Kelantan Trial Physics Paper 1 2009
Kelantan Trial Physics Paper 2 2009
Kelantan Trial Physics Paper 3 2009
Kelantan Trial Physics Scheme 2009

Terengganu Trial Physics Paper 1 2009
Terengganu Trial Physics Paper 1 2009 Answer
Terengganu Trial Physics Paper 2 2009
Terengganu Trial Physics Paper 2 2009 Scheme
Terengganu Trial Physics Paper 3 2009
Terengganu Trial Physics Paper 3 2009 Scheme

Force and Time

Does the FORCE (impulsive force) acting on a car during a collision depend on the time of impact only?
The SPM Physics syllabus seems to suggest this. It does not mention the change in momentum of the car.

From Equation 1 and Equation 2, it is clear that the impulsive force depends on the change of momentum and the time of impact. In SPM Physics, it is often stated that the impulsive force is inversely proportional to the time of impact WITHOUT stating that this is only true in situations where the change of momentum remains the same.

We should take note of this when we teach about impulsive force and time of impact.

Sharing Physics

Got inspired recently from the blog of a fellow teacher in my school. Revived my blog which was asleep for some time - to share resources for the benefit of anyone who needs some help with Physics at SPM or STPM level.

The Definition of Resistance Pt 2

View Blog
Can see Physics in a PET bottle used for carbonated drinks? Two days ago some of the students in my school are busy designing water rockets from used PET bottles. Yesterday was the Co-curriculum Day in my school. One of the highlights is the Water Rocket Competition organised by the panel of Physics teachers.
Back to the definition of resistance. Can resistance be also defined as the gradient of the V-I graph?
Consider Fig. 2, which shows the V-I relationship for two conductors X and Y. If resistance can be defined as the gradient of the V-I graph, then at current i, the resistance of Y is greater than X. If resistance is the ratio V/I, then at current i, both X and Y have the same resistance. So what does this show?
You cannot in general say that resistance is equal to the gradient of the V-I graph. This is only true for ohmic conductors.
In the Malaysian SPM 2006 Physics Paper 3, there is a question which gives a V-I graph as shown in Fig. 3.
The question goes on to say, "The gradient of the graph represents resistance. State how resistance varies with current."
In the light of what has been discussed, what do you have to say? If we leave out the first sentence in the question, "The gradient ..... ", can the question still be answered?
Bye for now.

Anonymous said...

Hi Koay, proud to see you joining the blogger group! Titles and topics of discussion are very relevant! Will recommend strongly to my circles of friends!

April 30, 2008 3:36 PM

Thinking Allowed said...

Hei! Koay. Glad that you are sharing your expertise with everyone. Physics is fun. But not everybody sees it that way. Hope you can show them how.

April 30, 2008 11:29 PM

The definition of resistance Pt 1

Look into any Physics book and you will see the definition for electrical resistance as shown above. In many books, voltage is stated as potential difference. For ohmic conductors, the voltage and current are directly proportional to each other provided the temperature and physical dimensions of the conductor remain constant. A graph of V against I will be as shown Fig 1. The gradient of the graph is constant and is equal to the ratio V/I for any value of the current. Now the gradient of the line is (change in V)/(change in I). In this particular case, the ratio V/I for different values of current is always equal to the gradient . Does this mean that resistance can be defined as V/I and also (change in V)/(change in I) ???

By the way, can anyone tell me whether it is possible to type formulae with ratios etc when posting a blog? Right now I have to insert it as an image. Quite troublesome.