@Akshath bruh

i think he writes normally, and then flip the video over, so we can read it.

Edward Huang I have been studying physics for about 3 years now and I guarantee you I would have never guessed that

@Akshath no shit sherlock

This is a glass table.. Camera put opposite to him

They mirror the footage

If it is mirror then the letters should also had to be in reverse direction .

He's writing on a glass panel......

Joey A he knows doubt anyone that dum lmao

I still have no idea

+实在哈哈 Thanks 实在哈哈, but I didn't write everything backwards (that's pretty hard). Check out the secret here: learningglasssolutions.com Cheers, Dr. A

Just trying to keep it honest. Cheers, Dr. A

Same.. but 3 years later

@@tytheguy1771 😂 if you have an exam soon, I wish you the best of luck man.

@@vesperowl3626 thank you, i write my final tommorrow morning, i need as much luck as possible

@@tytheguy1771 I wish you all the best man, tell me how it goes tomorrow ❤

@@vesperowl3626 88%! this vid definitely helped.

DESIGN CENTRE, You're very welcome. Glad you're enjoying the videos. You might also like my new site: www.universityphysics.education Cheers, Dr. A

Nicholas Tovbin, You're very welcome. Glad you're enjoying the videos. You might also like my new site: www.universityphysics.education Cheers, Dr. A

Hi Lee-Roy, thanks for the feedback. I'm not sure what you meant by your question. We are definitely using Ls, but only in conjunction with Li. The key factor in spring problems is "how far does it stretch from its equilibrium length" which means we want to use x = Ls - Li. For your second question, if the hanging mass is stationary (hence not accelerating), then the sum of the forces has to equal zero. Hope this helps. Cheers, Dr. a

+Victor Foresti Castro Thanks Victor, good luck on your test! Cheers, Dr. A

@@yoprofmatt .... hlo plz make a vedio on pulley's

Nicholas Haynes, Yes in theory. No in practice. Think of stretching the spring until the coiled wire is completely straight. Then it clearly won't act like a spring anymore. All springs will eventually behave nonlinearly, that is the restoring force is not proportional to stretch. Thanks for the comment, and keep up with the physics! You might also like my new website: www.universityphysics.education Cheers, Dr. A

For a helical spring with a circular wire, the formula that gives the spring constant in terms of its geometry is: k = G*d^4/(64*n*R^3) Where: G is the shear modulus of the material, a measure of its rigidity. d is the wire diameter n is the number of coils R is the radius of the centerline of the coils as they are wrapped around the helix. Two otherwise-identical springs, which are each initially built with the same number of coils, but different lengths, should have the same spring constant.

Correct! The board is called Learning Glass. You can check it out at www.learning.glass Cheers, Dr. A

Awesome. Re-explain it to me in a few years. Cheers, Dr. A

Zamaswazi, We usually put the negative sign in front of g. Thanks for the comment, and keep up with the physics! You might also like my new website: www.universityphysics.education Cheers, Dr. A

Yes, absolutely. But keep in mind that if you stretch it far enough (as with any spring), it will no longer be linear: the force will not be proportional to displacement. Cheers, Dr. A

The x-value for the equation F=k*x, would be 34 cm in this example. The force in the spring would be resisting the weight of the mass, plus the human force applied to it.

+Rae Clarke Hi Rae, good question! No, you'll have to get a little more complicated with your calculation. The important factor, other than K, is how far can the spring compress without "bottoming out." You will have to use conservation of energy to drop a mass from height h, compress the spring a distance x, and make sure that this distance x is still within the working distance of the spring. Give it a shot and let me know how it turns out. Cheers, Dr. A

+Matt Anderson Oh ok cool.. no prob I will.. thanks

+Rae Clarke Rae, just saw this video: kzbin.info/www/bejne/nKrboIpoZq9qg5o Thought you might be interested. Cheers, Dr. A

IDK I’m broke, No, not that hard. The board is called Learning Glass. You can check it out at www.learning.glass Cheers, Dr. A

@@yoprofmatt yes lolol, the comment section be very shocked that you can write backwards sksksk. Thanks for your wonderful explanation tho. Helped me a lot

Yes, absolutely. A spring is, after all, a piece of coiled wire. Stretch it far enough and the wire straightens out and no longer acts like a spring. Stretch it beyond its threshold limit, and it will snap. Cheers, Dr. A

Cynthia, Not quite. Remember that Li (8cm) is the rest length. That is, the length of the spring with no mass hanging on it. When we hang a mass of 2 kg it stretch the spring a distance x = 4 cm. See the discussion at the 2:40 mark in the video. (To calculate k in your equation, change your 8 cm to 0.04 m and you're good). Best of luck, and keep up with the physics! Cheers, Dr. A

thank you Dr Anderson so much for the response! let me ask this another way can you solve for k on a spring at rest, only knowing Li and mass? or is there a another equation to find x, only knowing Li and mass?

Since at rest kx=mg, there are three unknowns (k,x,m). You need to know two of these to get the other one with this equation. Rest length Li doesn't help you, because the important quantity is x: how far does it stretch from the rest length. Keep working with it. Cheers, Dr. A

Dr Anderson, thank you for helping me see (k) is only determined after measuring (x) thus true (x) can only be determined by field test, then math can determine changes with different (mg)s thereafter I was seeing since (k) is inherent it could be determined at rest (maybe it could but perhaps the spring's area, helix diameter and/or pitch would have to be formulated? just not by Hooke's) thanks again

+Beatrice Brown Great question. Springs add just like capacitors (and the opposite of resistors). Parallel: If you attach two springs in parallel, the effective new spring will be kp = k1 + k2. This means of course that you have made a "stiffer" spring (i.e. an object of weight mg will not stretch two springs as far, if both springs are attached directly to the object). Series: If you attach two spring in series, the effective new spring will be 1/ks = 1/k1 + 1/k2. This means of course that you have made a "weaker" spring (i.e. an object of weight mg will stretch two springs further, in total, than one spring). Hope this helps, and hopefully with this info you can design an experiment to test it out by hanging some masses from various combinations of springs. Cheers, Dr. A

thanks :) I've designed an experiment which we have to carry out this week, thanks again for your help :)

Yes. Then you would apply Earth's gravity 9.8 N/kg, to switch from mass in kg, to weight in Newtons. Mass = 50 grams = 0.05 kg Corresponding weight = 0.05 kg * 9.8 N/kg = 0.49 N deformation, suppose 2 cm, which is 0.02 m k = 0.49 N / 0.02 m = 24.5 N/m

Wire gauge is just a measurement of the wire diameter. And for historical reasons, a gauge with higher number is actually a smaller diameter. See en.wikipedia.org/wiki/Wire_gauge Cheers, Dr. A

Matt Anderson yes i understand that part you are telling me. But I was reading for some books when you are designing a spring. You have to choose a random wire diameter. My question was, how do you determine that diameter. I was reading that there are some security factor and things that assure the spring will work good

You should consult the book "Machinery's Handbook." Cheers, Dr. A

Thanks. Enjoy the physics. Cheers, Dr. A

Thanks, glad to be of help. Cheers, Dr. A

Awesome! Hope you nailed it. Cheers, Dr. A

@@yoprofmatt i sure did

1113 Himanshu Thakkar, Thanks for the comment, and keep up with the physics! You might also like my new website: www.universityphysics.education Cheers, Dr. A

Thank you for the comment. Keep up with the physics. Cheers, Dr. A

Good question. The short answer is that spring constants "add up in reciprocal" when you connect springs in series, and add up directly when you connect springs in parallel. So the answer is that the new spring constant becomes 3*k, when you cut a spring in 3 pieces. Here's why. Springs in series by definition, carry the same force (F) in each of them. Suppose we have identical 3 short springs, with a spring constant of c. Under load F, individually they would each deform a distance lowercase d. So for each individual spring, F = c*d. When we connect them in series, the deformations add up to a total deformation capital D. D = 3*d, because there are 3 springs deforming identically. Define as the spring constant of the three springs, such that F = k*D. Solve for k, k = F/D. Replace D with D=3*d, and get, k = F/(3*d) Replace F with F=c*d, and get k=c*d/(3*d). Result: k = c/3, or c = 3*k. The new spring constant after cutting a spring in thirds, is three times the original.

You are welcome. Keep up with the physics. Cheers, Dr. A

Tesla Tesla, Thanks for the comment, and keep up with the physics! You might also like my new website: www.universityphysics.education Cheers, Dr. A

Simply: mg = mass times gravity which in that case is 2 kg times 9.8 m/s^2 which if we calculate equates to 19.6 So now we have 19.6/X To solve for X you have to convert to SI units (metres in this case) and since you have 2 sizes one for initial size and the second for the stretched size you have to get the size between them which you get by doing L2 - L1, L1 being 8 cm and L2 being 12 cm So now we got 12 - 8 which equals 4 cm or 0.04 metres. If we plug the 0.04 metres into the equation you get: 19.6/0.04 Which equates to 490.

@@Naeromusic where did he get the 9.8?

@@MyCrazy4life You should read your physics book. It's the gravitational acceleration of the Earth. 9.8 meters per second squared (^2)

That's the gravitational acceleration at the surface of the Earth. Cheers, Dr A

Yeah bhi nahi pata toh dekh kyoun raha hai

USA. Cheers, Dr. A hey that rhymes

That sounds like a torsional spring constant, rather than a linear spring constant.

Glad to be of help. Cheers, Dr. A

Excellent question! Your first calculation is correct but the second one is not. Imagine this: you pull one block out a distance x. That amount of work is certainly 1/2*k*x^2. The "official" way to do this is to integrate the force (kx) from 0 to x. You integrated from zero because that was the rest length. The spring is not pulling on the block at this position. However, when you now pull out the second block, you have to integrate from x to 2x, since the block is initially being pulled on by the spring. When you do this properly, you end up with 1/2*k**(3x)^2. When you add this to the first answer, you get 2kx^2. Cheers, Dr. A

But when we are applying two opposite forces at the same time, then for both the forces isn't the spring starts getting stretched from its natural length x=0 ?

Yes, but the force is bigger than kx in that case. You are effectively cutting the spring in half (center stays fixed), and that means that k doubles (a short spring is stiffer than a long spring). So that's where you get your factor of two. Very good questions, though. Cheers, Dr. A

+Ignacio Olivares Ignacio, love it! This is great, and you are absolutely right that this is a better way to determine k. Since F = kx = mg, if we include a Δ on each side of the equation, we get kΔx = gΔm and therefore k = g(Δm/Δx). So all you have to do is add a bit more weight (Δm) and measure how far the spring stretched (Δx) and you can calculate k from the above equation. Cheers, Dr. A

+Matt Anderson that's fine. The best is making deltas on both sides of the equations. When students are doing the experiment it is useful to plot the data first in order they see the need to do kΔx = gΔm. This became now a very useful formula to measure spring constants. Is your image inverted?

+Ignacio Olivares Dr.I.

+Ignacio Olivares Indeed it is inverted. See this: kzbin.info/www/bejne/eYirfqeJg7Crj6M Cheers, Dr. A

Your majesty, Boards are available here: www.learning.glass (so are build instructions) Cheers, Dr. A

haha, you are the first to call me "Your majesty" 😅

I hope springs are included =P

William Scally that was punny. xD

www.learning.glass Cheers, Dr. A

+Abdullatif Alhor Abdullatif, glad you found it helpful. Stay tuned for more. Cheers, Dr. A

It is because when you resolve, you get kx-mg=0, assuming you take up as positive. The minus is there.

Emmett, You're very welcome. Glad you're enjoying the videos. You might also like my new site: www.universityphysics.education Cheers, Dr. A

Shadow Wind, Acceleration due to gravity. Thanks for the comment, and keep up with the physics! You might also like my new website: www.universityphysics.education Cheers, Dr. A

Benson, Thanks for the comment, and keep up with the physics! You might also like my new website: www.universityphysics.education Cheers, Dr. A

Great to hear. Thanks for the feedback. Cheers, Dr. A

The acceleration due to gravity near the Earth's surface is g = 9.8 m/s^2. Hope this helps. Cheers, Dr. A

That's just the acceleration due to gravity at earth's surface, its a value you should memorize.

9.8 is the force of gravity on any object on earth. 9.8 m/s^2

+muath jordan Muath, you are welcome. Keep up with the physics! Cheers, Dr. A

Doubt it. But I'll accept Mr. Anderson (but only if you say it in the cool "Matrix" way). Cheers, Dr. A

Mr. Annderrrsonnnn

Excellent. I can hear the Matrix tone coming through. Cheers, Dr. A

You are welcome. Keep up with the physics! Cheers, Dr. A

U welcome. Dr. A

Alpha Junior, Not writing backwards (I'm not that talented). The board is called Learning Glass. You can check it out at www.learning.glass Cheers, Dr. A

@matt anderson, omai

thanks

Okay, cool. Can I use the governor's mansion? Cheers, Dr. A

Mike Riddle using a mirror may be

Mike Riddle just invert the camera during editing

You're welcome! Cheers, Dr. A

Bevan A, You're very welcome. Glad you're enjoying the videos. You might also like my new site: www.universityphysics.education Cheers, Dr. A