It happens every time: You reach into your bag to pull out your headphones. But no matter how neatly you wrapped them up beforehand, the cords have become a giant Gordian knot of frustration.

有件事似乎無(wú)所不在:你把手伸到包包里拿出你的耳機(jī),但是無(wú)論之前你把耳機(jī)纏得如何整齊,耳機(jī)線總是會(huì)結(jié)成一個(gè)十分混亂的結(jié)。

Along with your Netflix stream inexplicably buffering and Facebook emotionally manipulating you, tangled cords are the bane of modern existence. But until we invent a good way of wirelessly beaming power through the air to our beloved electronic devices, it seems like we’re stuck with this problem.

除了Netflix的讓人莫名其妙的流媒體加載技術(shù)和Facebook對(duì)用戶的情緒控制實(shí)驗(yàn)之外,繞線耳機(jī)也應(yīng)該算反現(xiàn)代科技的一個(gè)存在。但是除非我們能發(fā)明一種比較好的無(wú)線輻射技術(shù)用于通過(guò)空氣介質(zhì)來(lái)連接我們所鐘愛(ài)的電子設(shè)備,否則我們只能繼續(xù)忍受這個(gè)問(wèn)題了。

Or maybe we can fight back with science. In recent years, physicists and mathematicians have pondered why our cords are such jerks all the time. Through experiments, they have learned there are many interesting ways to explain the science of knots. In 2007, researchers at the University of California, San Diego tumbled pieces of string inside boxes in an effort to find the ways that a cord can become tangled as it wanders around in your backpack. Their paper, “Spontaneous knotting of an agitated string,” helps explain how random motions always seem to lead to knotting and not the other way around.

或者我們能用科學(xué)予以還擊。近年來(lái),物理學(xué)家和數(shù)學(xué)家一直在反復(fù)研究有線耳機(jī)的纏繞問(wèn)題。通過(guò)實(shí)驗(yàn),科學(xué)家們發(fā)現(xiàn)有許多途徑能夠解釋繩結(jié)科學(xué)。2007年,美國(guó)加利福尼亞大學(xué)的研究員在盒子里放置了許多線繩并搖晃盒子,以觀察研究為什么耳機(jī)線在你的包里隨便纏繞亂作一團(tuán)的原因。他們的論文,“上下擺動(dòng)的線繩能自然地打結(jié)”也解釋了為什么隨意的搖動(dòng)總能讓線繩打結(jié),而不是有其他動(dòng)作。

Long floppy pieces of string can assume many spontaneous configurations. A string could be nicely laid out in a straight line. Or it could have one end crossed over some section in the middle. There in fact happen to be a lot of configurations where the string wraps around itself, potentially creating a tangle and eventually a knot. With relatively few of these random configurations being tangle free, chances are higher that the string will be a mess. And once a knot forms, it’s energetically difficult and unlikely for it to come undone. Therefore, a string will naturally tend toward greater knottiness.

長(zhǎng)而松散的線繩能隨機(jī)形成許多形狀。一條線繩能被拉成直線,當(dāng)然也也能從中間開(kāi)始交錯(cuò)盤(pán)桓。實(shí)際上,當(dāng)線繩自己纏繞起來(lái)之后,就能形成各種不同的形狀,而這也為線繩亂纏亂繞甚至打結(jié)創(chuàng)造了一個(gè)潛在的契機(jī)。只要有幾根這種不同形狀的線繩互相交結(jié)在一起,那么線繩胡亂打結(jié)的幾率將會(huì)大大提高。一旦出現(xiàn)了一個(gè)結(jié),那么再把它解開(kāi)就很困難了,甚至是不可能的。因此,自然而然地,一條線繩就總會(huì)比較容易打結(jié)。

Humans have been tying things up with string for many thousands of years, so it’s no surprise mathematicians have been working on theories of knots for a long time. But it wasn’t until the 1800s that the field really took off, when physicists like Lord Kelvin and James Clerk Maxwell were modeling atoms as spinning vortices in the luminiferous ether (a hypothetical substance that permeated all space through which light waves were said to travel). The physicists had worked out some interesting properties of these knot-like atoms and asked their mathematician friends for help with the details. The mathematicians said, “Sure. That’s really interesting. We’ll get back to you on that.”

人類用線繩捆系東西的習(xí)慣已經(jīng)維持上千年,因此數(shù)學(xué)家們長(zhǎng)久以來(lái)研究繩結(jié)的理論這事情一點(diǎn)也不稀奇。但是直到諸如開(kāi)爾文男爵和詹姆斯·克拉克·麥克斯韋利用原子建模描述以太(一種假象的無(wú)所不在的光波傳播介質(zhì))介質(zhì)中的漩渦流的19世紀(jì),這一領(lǐng)域才有所突破。物理學(xué)家們發(fā)現(xiàn)了這種類似繩結(jié)的球棍原子模型的一些有趣的性質(zhì),并找來(lái)他們的數(shù)學(xué)家朋友在細(xì)節(jié)上予以他們幫助。數(shù)學(xué)家們說(shuō):“行,這還真挺有趣,我們來(lái)幫你們吧?!?/div>

Now, 150 years later, physicists have long since abandoned both the luminiferous ether and knotted atomic models. But mathematicians have created a diverse branch of study known as knot theory that describes the mathematical properties of knots. The mathematical definition of a knot involves tangling a string around itself and then fusing its ends together so the knot can’t be undone (Note: This is kind of hard to do in reality). Using this definition, mathematicians have categorized different knot types. For instance, there is only one type of knot where a string crosses itself three times, known as a trefoil. Similarly, there is only one four-crossing knot, the figure eight. Mathematicians have identified a group of numbers called Jones polynomials that define each type of knot. Still, for a long time knot theory remained a somewhat esoteric branch of mathematics.

現(xiàn)在,150年過(guò)去了,物理學(xué)家早就拋棄了以太介質(zhì)理論和球棍原子模型。但是數(shù)學(xué)家卻創(chuàng)造了一個(gè)被稱為“扭結(jié)理論”的分支學(xué)科,來(lái)描述繩結(jié)的一些數(shù)學(xué)特性。數(shù)學(xué)中對(duì)于繩結(jié)的定義是一個(gè)線繩自己纏繞且兩端需要捻合起來(lái),保證繩結(jié)無(wú)法被解開(kāi)。根據(jù)這一定義,數(shù)學(xué)家將繩結(jié)分為了不同的種類。比如說(shuō),當(dāng)一條線繩自己纏繞三次后,只能形成一種繩結(jié),被稱為三葉結(jié)。同樣,纏繞四次也只能形成一種繩結(jié),叫做八字結(jié)。數(shù)學(xué)家證明出了被稱為“瓊斯多項(xiàng)式”的一系列公式用以定義每一種繩結(jié)。一直以來(lái),扭結(jié)理論在數(shù)學(xué)領(lǐng)域仍然是某種充滿奧秘的分支學(xué)科。

In 2007, physicist Douglas Smith and his then-undergraduate student Dorian Raymer decided to look at the applicability of knot theory to real strings. In an experiment, they placed a string into a box and then tumbled it around for 10 seconds. Raymer repeated this about 3,000 times with strings of different lengths and stiffness, boxes of different size, and varying rotation rates for the tumbling.

2007年,物理學(xué)家Douglas Smith和他當(dāng)時(shí)的本科同學(xué)Dorian Raymer決定將扭結(jié)理論應(yīng)用到真實(shí)的線繩中去。在一次使用中,他們?cè)诤凶永锓胖靡粭l線繩并搖晃10分鐘。Raymer以不同長(zhǎng)度和不同軟硬度的的繩子、不同尺寸的盒子、以及不同的搖晃頻率重復(fù)了三千次。

They found that about 50 percent of the time, a string would emerge from its quick spin with a knot in it. Here, there was a big dependence on the string’s length. Short strings—those less than about a foot in a half in length—tended to stay knot-free. And the longer a string got, the greater the odds of knot formation became. Yet the probability only increased up to a certain size. Strings longer than five feet became too cramped in the boxes, and wouldn’t form knots more than roughly 50 percent of the time.

他們發(fā)現(xiàn),一根線繩在快速搖晃后打結(jié)的概率會(huì)達(dá)到50%。而且,這也與線繩的長(zhǎng)度有很大的關(guān)系。比較短的繩子——少于一個(gè)半英尺——一般不會(huì)打結(jié)。越長(zhǎng)的線繩,打結(jié)的可能性就越大。但是這一概率隨繩結(jié)變長(zhǎng)到一定程度就停止了。超過(guò)5英尺的繩子在盒子里就會(huì)無(wú)計(jì)可施。

Raymer and Smith also classified the types of knots they found, using the Jones polynomials developed by mathematicians. After each tumble, they took a picture of the string and fed the image into a computer algorithm that could categorize the knots. Knot theory has shown that there are 14 kinds of primary knots, which involve seven or fewer crosses. Raymer and Smith found that all 14 types formed, with higher odds of forming simpler ones. They also saw more complicated knots, some with up to 11 crossings.

Raymer和Smith也利用數(shù)學(xué)家推算出的瓊斯不等式給所形成的繩結(jié)分了類,每次搖晃之后,他們都會(huì)給線繩拍一張照片并將照片上傳至一個(gè)用于給繩結(jié)分類的電腦算法程序中。扭結(jié)理論對(duì)于少于等于7個(gè)結(jié)的初級(jí)繩結(jié)給予14種分類。然而二人還發(fā)現(xiàn)了更加復(fù)雜的繩結(jié),有些繩結(jié)竟然高達(dá)11個(gè)結(jié)。

The researchers created a model to explain their observations. Basically, in order to fit inside a box, a string has to be coiled up. This means the end of the string lies parallel to different segments along the length of the string. As the box spins, the string end has a certain chance of falling over and around one of these middle segments. If it moves enough times, the end will essentially braid itself around some part in the middle, tangling up the string and creating different knots.

研究員們創(chuàng)造了一個(gè)模型用以解釋他們的觀測(cè)結(jié)果。為了適應(yīng)盒子,線繩必須要以一種卷曲的姿態(tài)待在其中,這意味著繩子末端與繩子的不同部分會(huì)平行排放。隨著盒子晃動(dòng),繩子末端有充分的機(jī)會(huì)上下翻滾并與繩子中段的諸多部分相遇。如果搖晃了充足時(shí)間,繩子末端就會(huì)與繩子中部纏繞在一起,從而形成不同的繩結(jié)。

The most important question from these experiments is what can be done to keep my cables from getting all screwy. One method that decreased the chances of knot formation was placing stiffer strings into the tumbling boxes. Perhaps this is what motivated Apple to make the power cables for more recent generations of laptops less flexible. It also helps explain why your long, thin Christmas tree lights are always a tangled mess while your shorter and stockier surge protector cable stays relatively smooth.

這些實(shí)驗(yàn)所要解決的最重要的問(wèn)題就是,如何讓繩子保持不纏繞不打結(jié)。一種能夠降低繩子打結(jié)幾率的方法就是在盒子里放置一些比較硬的繩子。也許這也是積極進(jìn)取的蘋(píng)果公司最近幾代的筆記本電腦電源線不那么容易纏繞的原因。這也解釋了,為什么圣誕樹(shù)上又細(xì)又長(zhǎng)的彩燈線總是打結(jié),而電涌抑制器那粗短堅(jiān)硬的電線卻相對(duì)來(lái)說(shuō)不那么容易亂。

A smaller container size also helped keep the knots away. Longer strings pressed against the walls of a small box, preventing the cord from falling over itself and braiding up. This has been proposed as the reason why umbilical cord knots are rare (happening in about 1 percent of births): The womb is too small to allow for the organ to tangle around itself. Finally, spinning the boxes faster than normal helped prevent knotting because the strings were pinned to the sides by centrifugal forces and couldn’t braid themselves. However, I’m not sure how you would apply this to your own pocket dilemma of cord tangles. Perhaps you could travel around by quickly somersaulting everywhere. Or buy clothes with really tiny pockets.

更小的容器體積也是防止打結(jié)的妙招之一。小盒子將較長(zhǎng)的線繩緊緊束縛住,從而阻止了線繩上下移動(dòng)并打結(jié)。而這可能也是為什么臍帶很少打結(jié)的原因(在新生兒中僅有1%的發(fā)生幾率):母親的子宮空間太小了,臍帶難以互相纏繞。最后,以更快的速度搖動(dòng)盒子也可以防止線繩打結(jié),因?yàn)槔K子受到離心力的作用會(huì)被固定在盒子邊緣,從而無(wú)法纏繞打結(jié)。在現(xiàn)實(shí)生活中,也許你要么走到哪兒都快速地翻攪著你的口袋,要么就得買一些比較小口袋的衣服了。