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2017年
02月04日
08:04 bbbcさん

The sonic boom problem (超音速の爆音)

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ソニックブーム(sonic boom)とは、超音速飛行の衝撃波による大音響のこと。
英語はゆっくりで学習向き。 分かりやすい説明で、専門語は少ない。

 06分 155wpm                         2017年    

字幕 : 開始後 で字幕On/Off、 で言語選択。文字の色やサイズ゙はオプションから。
.     動画を見るとき、 でフルスクリーンに拡大すると見やすい。

下記英文は ポップアップ辞書 が使えます。
  テキストはこちら⇒英日トランスクリプト (字幕はYouTubeの方が大きく見やすい)     

Humans have been fascinated with speed for ages. The history of human progress is one of ever-increasing velocity, and one of the most important achievements in this historical race was the breaking of the sound barrier.

Not long after the first successful airplane flights, pilots were eager to push their planes to go faster and faster. But as they did so, increased turbulence and large forces on the plane prevented them from accelerating further.

Some tried to circumvent the problem through risky dives, often with tragic results. Finally, in 1947, design improvements, such as a movable horizontal stabilizer, the all-moving tail, allowed an American military pilot named Chuck Yeager to fly the Bell X-1 aircraft at 1127 km/h, becoming the first person to break the sound barrier and travel faster than the speed of sound.

The Bell X-1 was the first of many supersonic aircraft to follow, with later designs reaching speeds over Mach 3. Aircraft traveling at supersonic speed create a shock wave with a thunder-like noise known as a sonic boom, which can cause distress to people and animals below or even damage buildings. For this reason, scientists around the world have been looking at sonic booms, trying to predict their path in the atmosphere, where they will land, and how loud they will be.
 Mach :マッハ(速度/音速)、発音は英語では ['mɑːk] なので注意。

To better understand how scientists study sonic booms, let's start with some basics of sound. Imagine throwing a small stone in a still pond. What do you see? The stone causes waves to travel in the water at the same speed in every direction. These circles that keep growing in radius are called wave fronts. Similarly, even though we cannot see it, a stationary sound source, like a home stereo, creates sound waves traveling outward. The speed of the waves depends on factors like the altitude and temperature of the air they move through. At sea level, sound travels at about 1225 km/h.

But instead of circles on a two-dimensional surface, the wave fronts are now concentric spheres, with the sound traveling along rays perpendicular to these waves. Now imagine a moving sound source, such as a train whistle. As the source keeps moving in a certain direction, the successive waves in front of it will become bunched closer together.

This greater wave frequency is the cause of the famous Doppler effect, where approaching objects sound higher pitched. But as long as the source is moving slower than the sound waves themselves, they will remain nested within each other. It's when an object goes supersonic, moving faster than the sound it makes, that the picture changes dramatically.
 Doppler effect :ドップラ-効果、 音源が動くと振動数が変る現象。 例は救急車のサイレン

As it overtakes sound waves it has emitted, while generating new ones from its current position, the waves are forced together, forming a Mach cone. No sound is heard as it approaches an observer because the object is traveling faster than the sound it produces. Only after the object has passed will the observer hear the sonic boom.

Where the Mach cone meets the ground, it forms a hyperbola(双曲線), leaving a trail known as the boom carpet as it travels forward. This makes it possible to determine the area affected by a sonic boom. What about figuring out how strong a sonic boom will be? This involves solving the famous Navier-Stokes equations to find the variation of pressure in the air due to the supersonic aircraft flying through it. This results in the pressure signature known as the N-wave.
 Navier-Stokes equations :ナビエ・ストークス方程式、流体力学の基本式。
                  流体での ニュートンの F=mα に相当。 難しい偏微分の式


What does this shape mean? Well, the sonic boom occurs when there is a sudden change in pressure, and the N-wave involves two booms: one for the initial pressure rise at the aircraft's nose, and another for when the tail passes, and the pressure suddenly returns to normal. This causes a double boom, but it is usually heard as a single boom by human ears.

In practice, computer models using these principles can often predict the location and intensity of sonic booms for given atmospheric conditions and flight trajectories, and there is ongoing research to mitigate their effects. In the meantime, supersonic flight over land remains prohibited. So, are sonic booms a recent creation? Not exactly. While we try to find ways to silence them, a few other animals have been using sonic booms to their advantage.

The gigantic Diplodocus may have been capable of cracking its tail faster than sound, at over 1200 km/h, possibly to deter(阻止する) predators(捕食者). Some types of shrimp can also create a similar shock wave underwater, stunning or even killing pray at a distance with just a snap of their oversized claw. So while we humans have made great progress in our relentless(執拗な) pursuit of speed, it turns out that nature was there first.
 Diplodocus:ディプロドクス 1億5千年前、北米にいた体長30m位の大型恐竜
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2017年
02月04日
17:44
bbbcさん

参考
 YouTube や 写真で マッハコーンによく似たきれいな画像が載っているが、
 音速より低いベイパーコーンである (断熱圧縮・膨張による急冷水蒸気)。
 本解説にもあるとおり、ソニックブームは窓ガラスが割れるほどの爆音と衝撃。
 超音速飛行は地上近くでは禁止されており、素人には撮影できない。
 ベイパーコーンはすぐには消えない。 マッハコーンは一瞬で肉眼では見えない。
         

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