Lookie There

So here are a couple pics from the past which relate to the stuff we are learning now…if only I knew this stuff then, haha. I didn’t have a chance to upload any from this weekend, so I dug into my pictures folder. The first one of the Washington Monument reminded me of the lab we did where we measured the shortest possible height of a mirror to put in our house. Between the Washington Monument and the Lincoln Memorial is a GIANT reflecting pool that allows you to see the Monument’s entire reflection when standing on the steps of the Lincoln Memorial. Unfortunately that day we went to the Lincoln Memorial was the same day we visited the White House so I didn’t have my camera handy. The first pic is one I took, but the second one that I found is better…thanks Google images!! I looked up the measurements of the pool’s length and the Monument’s height, and they are not 1:2. However, because it seemed like the reflection of the Monument fit so snuggly in the pool, I figured that there must be a different ratio between the two; one which factors in the fact that the pool (mirror) is on the ground and the viewer is standing on the steps ant the Memorial. That would’ve been a killer lab. Moving on. The other picture that I have up is of a crystal ball..ooohhh. I took this pic at the Museum of Natural History (yay! Night at the Museum) and the crystal ball itself actually acts as a lens because of its spherical shape. From what I witnessed while playing with converging lenses today, I realized that because of the distance I viewed the ball relative to its center, I passed the object’s focal length and therefore saw that an inverted image of the other side of the room. And as I viewed the room, I moved my head gradually backwards, which altered the size of the image; another thing which I saw today in class. Unlike when dealing with mirrors (distance doesn’t affect image), when using lenses, image size relates inversely with object distance.

ambulance hunt

Waaay cooler than an ambulance! :)

nah, jk. same idea here as with the ambulance.

to infinity and beyond...

Watch it in high quality! (HQ)

Like I said, physics is everywhere; infinity beyond included. During class the other day we were learning about standing waves. The demonstration with the fan and strobe light was the best so far, hands down, but it reminded me of something even cooler: this thing I saw at California Adventure. I instantly thought of the relation because of the sight of the flashing strobe lights. It was the same sight that made us leave the exhibit because it made our friend, who already wasn’t feeling good from Tower of Terror, queasier. I didn’t really know the exact name of this supercool thing, so I googled it using toy story and strobe light. I found out that the thing was actually a zoetrope, or a pre-cinematic rotating device that creates the illusion of movement. The Toy Story zoetrope is a modern zoetrope in 3D, and uses flickering strobe lights to simulate movement. It was created in 2006 during Pixar’s 20th anniversary animation celebration and was brought to California Adventure’s animation building to demonstrate animation. The zoetrope has a bunch of Toy Story character models, and the adjacent models of a single character represent what usually are sequential frames of film; meaning that each model varies slightly in shape or action—like a flipbook). This is what you will see during the first part of the clip. You won’t get the full animation effect until the lights get dim and the strobe lights turn on. Like in standing waves, and our demonstration with the fan, the frequencies of both the strobe lights and the spinning models match, therefore creating the effect of animation. The term standing wave is often applied to a resonant mode of an extended vibrating object. The resonance is created by constructive interference of two waves which travel in opposite directions in the medium, but the visual effect is that of an entire system moving in simple harmonic motion or ANIMATION! The models actually spin once per second, too fast for any eyes to comprehend, but when the strobe light flashes which occur 18 times per second, they produce standing waves, which we are able to perceive as movement. If the frequency of the flashing were to increase and still match the movement of the models, we would see more movement; like how in class when we reached increasingly higher harmonics, we saw for example, 6 blades instead of 3. Well, hope the clip works; I figured it’d be better than my super short one.

disneyland baby!

Over spring break I went on the California College Tour where T-Flem, our fearless leader, took us through the darkness that is college. But physics was never far from our minds-the stuff was everywhere! Even at Disneyland, where school should be far from our minds, physics kept popping up. While in line for Astro Blasters, I saw a GIANT etch a sketch and batteries, and basically all of the rides (like California Screamin and Splash Mountain) just oozed physics. So the etch a sketch stood out mainly because we just covered magnetism and those fun metal shavings. Even though in class I think we played with magna doodles, the etch a sketch does contain aluminum powder which clings to the screen. And the batteries were a pleasant reminder of the numerous labs in which we conducted electricity and learned to complete circuits. Moving onto California Screamin, I was able to truly see the power of potential energy. When the ride first started, we were shot up the first hill super fast. But once we hit the top of that first hill, the conversion of potential energy to kinetic energy was what drove us through the rest of the ride. And if I had too, I could draw the FBD as we flew through the loop in the middle of the ride. Hah. We experienced free fall as well during Tower of Terror. After ascending to the top of the "elevator shaft" for a moment we were suspended in the air then suddenly fell, under the force of gravity. And even though all of the riders were different masses, we all fell with the same acceleration. In Splash Mountain, physics truly prevails because no seat belts are used. Even though some of us slightly lifted off our seats, physics kept us safe. And come to think of it, all throughout the park, we could hear the doppler effect in action as riders screamed at ridiculous frequencies as the zoomed through the rides. Overall the trip was a fat plus and Disneyland definitely added to it. Even though it was a bit much when our thoughts kept getting interrupted by physics realizations (and at Disneyland too!), it was a good feeling knowing how things worked. I guess other people feel the same way cuz my uncle said that Disney has this education series where they teach kids the physics behind all the magic. But I gotta say; I think my physics encounters with Disneyland were pretty cool already.

motor!

VICTORY!!

try this at home:static electricity

I don’t whether it was because it was humid last night or what, but this took time! Anyways, basically, the charge on the balloon attracts the molecules of water in the stream. Since the molecules can easily move, the stream bends. First, I created a charge on the water balloon through friction (rubbing the balloon against my head caused electrons to transfer from my head to the balloon). Water is a polar molecule (meaning it’s neutral), as we learned, meaning that it has a dipole moment (oxygen end slightly negative and the hydrogen end slightly positive). As the balloon (which in this case is positive), nears the stream, the balloon’s electric field causes the water molecules to align. This is possible because opposite charges attract and the charges in the water orient themselves so that their negative ends move closer to the balloon and their positive ends turn away from the balloon. So, the net force of the water molecules is moving towards the balloon, deflecting the stream of water towards it. If the balloon accumulated a negative charge, the reasoning for the deflection would be similar, but opposite. Hope you can see the deflections...not super big, but there!

meter reader

I found it!! I asked my dad where it was and he told me that our meter is on the side of our house by the swimming pool pump stuff. It's not visible from the sidewalk and to get to it you either have to go through our backyard or garage. So, I asked my dad how they read it and he said that now they can just drive by and pick up the readings electronically. Pretty efficient. I didn't know but my friend, well his dad, is a meter reader for HECO--that's how my dad found out. Neat. I wonder how many kwh we've burned through...nice my hat, yah? but I don't know why it says Hines

MAGNificET indiana jones

So this Saturday, I went over to Remi’s to do some APUSH studying. But, like all of our “study sessions,” we quickly lost focus and somehow wandered over to the tv. That day we watched some Indiana Jones, Real Housewives of NYC, Hairspray, and did some Richard Simmons—hah! I love the Indiana Jones movies and always got caught up in the action. But this time, while watching the latest: Indiana Jones and the Kingdom of the Crystal Skull, I had the knowledge of physics with me. So, I knew better when I saw Indy and the Cate Blanchett lady, with her posse, trying to locate the “highly magnetized box.” At this point in the movie, Indy is kidnapped by the Russians and is being forced to find a box in a giant warehouse. The box has alien remains in it and Indy says that it is super magnetic. To locate it he takes some gunpowder out of a hand grenade and tosses it in the air. The "metal" in the gunpowder is then floats across the room to the box. While gunpowder does look a lot like iron filings, it contains no metal and is more like coffee grounds than powder. If you toss it up like Indy does, it would fall straight to the ground. And gunpowder in the presence of a strong magnetic field does NOTHING. As Indy approaches the box, he calls for a shotgun shell. He then breaks it open and pours out the lead buckshot pellets which instantly are attracted to the box and cling to its exterior. But I looked it up and wikipedia says lead is not even magnetic, it’s diamagnetic; which means that it is slightly repelled by magnetic fields. As the box is moved, even the warehouse lights bend toward it. Despite the metal lights are strongly attracted to the box’s contents, the Russians are able to load the box onto a metal truck and easily slide it forward. Later on, the “magnetic” skull attracts gold coins too. But gold is also diamagnetic and Shia even says that gold isn’t magnetic…I still love Indy, even with all of the movie blunders. But at least now I know that if I ever am forced to find a highly magnetic item, gunpowder probably isn’t my best bet.

light ON

Long weekends are the best! But now it’s Monday night and I have to do all of my homework… I didn’t take much pics this weekend so I thought about what I’d blog as I was getting ready for dinner. Then suddenly, as I sat down, a light went off both in and above my head! My sister had turned on the light above our dining table—reminding me of variable resistors and light dimmers. The light switch for that particular light is a circular knob that you push to turn on/off and turn to adjust the brightness; however there are light dimmer switches can also be used by sliding a lever. In the case of my light, a simple method was devised to adjust light levels: variable resistors. A typical resistor is made of a material that doesn't conduct electrical current well. A variable resistor is made from a resistive material comprised of a stationary and a moving contact arm. In the second picture, I captured the knob and drew its basic components (sorry it's messy..i drew it in on my camera). The total resistance of the resistor in this case is varied by adjusting the distance the current has to flow through the resistive material. In my illustration, the moving contact arm is touching the bottom right portion of the resistor. By turning the knob to the left, the contact arm moves in the counter-clockwise direction; thus decreasing the distance the charge has to travel. So when this occurs, the contact arm is to the left and the charge only has to travel through a small amount of resistive material—brighter light! Similarly, when the contact arm is in a position similar to the one I drew, the light emitted is dimmer because the charge has to move through more resistive material. Physics is so illuminating!

SHOCKing!

Ahh this weekend was exciting! Even though the Cardinals lost (they had it!!), and BJ Penn, well..., it was my bday and there was an extra long Office :D Even thought there was a ton of physics involved, I didn’t get a chance to take any pictures of the fight or game. So, I was thinking of what we were learning in class and dug up this picture from this past spring break. Here’s Remi and me on our uber epic trip, waiting for the Bellagio water show to start. These shows never disappoint—one of them was even set to Andrea Bocelli’s, “Time to Say Goodbye!” And although we thought Vegas wasn’t going to be that fun, since our parents planned that part of the trip..(and we were waiting for Disneyland), we got to see “Love,” and experience physics firsthand. As we learned in class, objects usually tend to be neutral. We included, like to remain in a neutral state, but sometimes charge imbalances do occur. Since objects like to be in neutral states, when they lose their balance of protons and electrons, they want to either lose or gain electrons to return to neutrality. Objects reduce their charge imbalances immediately when their electrons are given the freedom to flow. Getting shocked is an example of this occurance. Here in Hawaii, moisture in the air (caused by our consistently humid climate) reduces charge imbalances on its own so we rarely experience shocks. In places with drier climates such as Las Vegas, however, shocks are common. This difference in weather therefore made us subject to more severe static shocks than the ones felt back at home. One place static electricity was eveident was at our hotel room door. I’ve experienced shocks in Vegas from opening doors before, but none quite as “big” as one of the ones I recieved early one morning. On our last night in Vegas, we stayed out later than usual to take in our last sights of the city. The next morning, I had the hardest time waking up because I was tired and the cool weather just made me want to stay in bed! But I slowly got ready. Dragging myself around the room, I got my stuff together and headed for the door. When I reached out to turn the handle, I felt a shock surge through my body! I realize now that the magnitude of the shock was so great because I was accumulating electrons from the floor each time I dragged my foot on the carpet. By the time I reached the door, my body had a negative charge and wanted to return back to a neutral state. So when I finally came in contact with the handle, the electrons in my body rushed towards the neutral doorknob, resulting in a shock. Static electricity was also evident in my hair. Especially when I brushed it in the mornings, I could “feel” my hairs repelling each other, and see it in the mirror. This effect came from the electrons I received from the carpet as well. So, next time in Vegas, I’m gonna use all of this knowledge of charge to create a monster shock for my sister! ;)

ouch. when physics hits back

This past weekend while at my grandparents’ house, my cousins brought their airsoft guns. So we went to backyard to play with them and shoot some cans and water ballons while we waited for lunch to be ready. Airsoft has a lot to do with physics. The guns which we used were electric and were powered by rechargeable batteries. My uncle said that the batteries power an electric motor that turns a gear box or something which compresses a spring. The tension from the spring is then released, sending the plastic BBs through a chamber and out of the barrel. The tension created in the spring must be pretty immense because those BBs fly right out of those guns! With such small masses, it makes sense that they move so fast. However, a smaller mass leaves the BBs susceptible to wind and stuff which can lower accuracy. So, different masses of BBs are used. But if you think about it, the pellets can’t be that heavy, or else they wouldn’t be able to move quickly or hit far targets, so their amount of KE transferred can’t be that big (E=1/2mv2). This means that BBs aren’t super damaging, when compared to larger paintballs for example. I learned this firsthand when my cousin shot me in the leg. Because of the small mass of the pellet and long distance between me and him and his gun, the shot hurt, but not that much. This makes sense because since the pellets we were using were of a small mass, they had small inertias. And although they were shot at higher velocities than other heavier pellets would be, they also lost speed quickly; therefore minimizing the hurt I felt when the BB finally reached me. The flight and flight path of the pellets also are physics related. When we shot the BBs this weekend, because we were aiming for cans and other things close by, their paths appeared perfectly horizontal. But when shooting the gun at a slightly upward angle the other weekend, I could see the parabolic flight of the pellet. My neighbors own Toys n Joys and my uncle likes to play with the airsoft guns. So the other weekend he brought home an airsoft gun that had this tracking thing so the pellets glowed in the dark! It was a perfectly clear and dark night so we all stopped our football game and told our uncle to get the gun. Standing in his driveway, my uncle aimed the gun kind of upwards and we could see its path clearly...it was parabolic :-) The way the BBs fly is physics too and is at the hand of Bernoulli’s principle—the same principle through which airplanes get lift. Airsoft—more fun thanks to physics.

christmas phun

So this winter break was really fun and thankfully pretty restful…I wish it didn’t have to end so soon :/ But now on to the physics part. During our very cold soccer trip to San Francisco, you couldn’t help but being surrounded by the stuff. Even in our transportation—from our airplane ride into SFO, our van rides to the field, and BART ride into the city, we experienced displacement and acceleration among other things. Our total displacement for our trip for example was zero because we flew a bunch of miles to San Francisco, but flew about the same mileage back to Honolulu (in the opposite direction). While in our vans, we exerted a weight on the road which exerted a normal force back, allowing us to drive on the road. On the BART, we went through both positive and negative acceleration as we travelled in opposite to and from the city (Union Square). And even though we didn’t ride the cable cars this time, we watched them run up and down Powell Street as we went in and out of the stores. These cable cars run on a system of underground steel cables and pulleys, maintaining a constant velocity and tension. The actual soccer portion of our trip also embodied physics. When we struck the ball to make a pass or take a shot, we most of the time hit the ball off center, exerting a torque on the ball and therefore causing the ball to spin. And even though most of us can’t bend it like Beckham (yea that’s us, haha)…we could curve the ball enough for the most part to avoid a defender or play a good cross into the box. So here's us in our van, on the BART, with David Beckham ;) and making a pitstop on the way back to the hotel next to a really pretty tree. Wow that's a lot...I guess I'm feeling picture happy tonight

Back at home physics was present as well. Last night some of my friends and I went to Hawaiian Brian’s and played pool..and I didn’t lose! Well as the cue ball struck another ball, I witnessed an elastic collision and saw energy (almost completely) being conserved…just like in our homework problems. The initially stationary cue ball would move thanks to an outside force (you and your pool stick) then would transfer its kinetic energy to the ball you are aiming for. This exchange along with the help of the friction between the ball and the pool table causes the cue ball to stop and hopefully (if you’re good) the other ball to roll into a pocket.
Merry Christmas and Happy Holidays!