Monthly Archives: April 2012

EPR paradox, 3

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It turns out that the usual rules for combining quantum mechanical and classical descriptions violate the principle of locality without violating causality.

Causality is preserved because there is no way for Alice to transmit messages (i.e. information) to Bob by manipulating her measurement axis. Whichever axis she uses, she has a 50% probability of obtaining “+” and 50% probability of obtaining “-“, completely at random; according to quantum mechanics, it is fundamentally impossible for her to influence what result she gets.

Furthermore, Bob is only able to perform his measurement once: there is a fundamental property of quantum mechanics, known as the “no cloning theorem”, which makes it impossible for him to make a million copies of the electron he receives, perform a spin measurement on each, and look at the statistical distribution of the results. Therefore, in the one measurement he is allowed to make, there is a 50% probability of getting “+” and 50% of getting “-“, regardless of whether or not his axis is aligned with Alice’s.

— Wikipedia on EPR paradox

In fact, a theorem proved by Phillippe Eberhard shows that if the accepted equations of relativistic quantum field theory are correct, it should never be possible to experimentally violate causality using quantum effects (see reference [6] for a treatment emphasizing the role of conditional probabilities).

— Wikipedia on Delayed choice quantum eraser

2012.04.08 Sunday ACHK

Demo Day

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Err on the side of speaking slowly. At Rehearsal Day, one of the founders mentioned a rule actors use: if you feel you’re speaking too slowly, you’re speaking at about the right speed.

What you need to do is talk in this artificial way, and yet make it seem conversational. (Writing is the same. Good writing is an elaborate effort to seem spontaneous.)

The problem is, as you approach (in the calculus sense) a description of something that could be anything, the content of your description approaches zero.

So we concentrate on the basics. On Demo Day each startup will only get ten minutes, so we encourage them to focus on just two goals: (a) explain what you’re doing, and (b) explain why users will want it.

— Paul Graham

2012.04.08 Sunday ACHK

Transcender 1.2.3

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這段改編自 2010 年 3 月 20 日的對話。

你現在有沒有問題,需要給我去 transcend 一下?

(安:沒有。但是我想問,「transcend」這個字的中文翻譯是什麼?)

這個字翻譯了的話,就再沒有原本的神髓。例如,你可以用「超越」或者「看化」。它們的意思,和「transcend」非常接近,但感覺不大相同。

當你講「超越問題」時,別人不會知道你的意思。解釋「超越問題」的時間,不會比解釋「transcend」這個字的時間少。你用「看化」的話,又好像帶點滄桑和消極。

(安:如果用「轉化」呢?)

「轉化」就好像是指,由一樣東西,變成同一層次的另一樣東西。它缺乏了「transcend」之中,「跳高一個層次看」和「騰雲架霧」的意思。

— Me@2012.04.08 

2012.04.08 Sunday (c) All rights reserved by ACHK

Bell’s theorem, 3

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EPR paradox, 2

Two assumptions drove the desire to find a local realist theory:

1. Objects have a definite state that determines the values of all other measurable properties, such as position and momentum.

2. Effects of local actions, such as measurements, cannot travel faster than the speed of light (in consequence of special relativity). Thus if observers are sufficiently far apart, a measurement made by one can have no effect on a measurement made by the other.
   
— Wikipedia on Bell’s theorem

It is no longer possible to adhere to both the principle of locality (that distant objects cannot affect local objects), and counterfactual definiteness, a form of ontological realism implicit in classical physics. Some interpretations of quantum mechanics hold that a system lacks an actualized property until it is measured, which implies that quantum systems exhibit a non-local behaviour. Bell’s theorem proved that every quantum theory must either violate local realism or counterfactual definiteness.

— Wikipedia on Naive realism

1. The principle of locality:

There are two possible meanings of “locality” here.

1.1 The principle is correct in a sense that no causal influence can be faster than light.

1.2 The principle is incorrect in a sense that distant particles can be entangled. Correlation without causation can be instantaneous.

Assume that a pair of particles are entangled. Measuring one particle will collapse the wave function, which governs both particles, instantaneously.

2. Counterfactual definiteness:

2.1 It is correct in a sense that an object has a definite quantum state.

2.2 It is incorrect in a sense that, most often than not, the definite quantum state is not corresponding to a definite classical state (aka eigenstate). Instead, that quantum state is a superposition of different eigenstates. 

— Me@2012-04-07 11:36:01 AM

2012.04.07 Saturday (c) All rights reserved by ACHK

Digital physics, 4

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Moreover, there is this statement that “distances smaller than Planck length don’t exist” that confuses many people. They heard it and misunderstood it, thinking it applies to coordinate differences. It can only apply to Lorentz-invariant “proper” distances, otherwise relativity is broken.

– Lubos Motl Jan 23 ’11 at 8:19

2012.04.06 Friday ACHK

Transcender 1.2.2

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這段改編自 2010 年 3 月 20 日的對話。

又例如,有學生問我,他來不及「完成所有功課」時,應該怎麼辦。回答時,我並不是教他如何「完成所有功課」,而是解釋為何「完成所有功課」,並不是重點。

做功課只是手段,不是目的。做功課的最終目的,並不是「完成功課」。做功課的最終目的,是透過做功課,去奪取最多的學術知識和考試分數。

所以,我叫他要懂得權衡輕重,先做成本效益最高的東西。其他功課,無論有多麼掛念,都應暫時完全拋諸腦後,直到完成第一要務為止。那就可以保證,即使完成不了功課,成績也不致太差。換句話說,他應透過解決真正的問題,去避開原本的問題。

真正的問題是「如何奪取最多的分數」。原本的問題「如何完成所有功課」,只是表面的問題,所以可以 transcend 掉,毋須理會。

你現在有沒有問題,需要給我去 transcend 一下?

(安:沒有。但是我想問,「transcend」這個字的中文翻譯是什麼?)

這個字翻譯了的話,就再沒有原本的神髓。

— Me@2012.04.06 

2012.04.06 Friday (c) All rights reserved by ACHK

Godel 1.1

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A major early proponent of formalism was David Hilbert, whose program was intended to be a complete and consistent axiomatization of all of mathematics. Hilbert aimed to show the consistency of mathematical systems from the assumption that the “finitary arithmetic” (a subsystem of the usual arithmetic of the positive integers, chosen to be philosophically uncontroversial) was consistent (i.e. no contradictions can be derived from the system).

Godel’s conclusion in his incompleteness theorems was that you cannot prove consistency within any axiomatic system rich enough to include classical arithmetic.

— Wikipedia on Formalism (mathematics)

2012.04.05 Thursday ACHK

diff 2c

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real world + you = your ideal world     

— Me@2012-03-29 11:16:43 AM

2012.04.05 Thursday (c) All rights reserved by ACHK

Perseverance

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Perseverance is important because, in a startup, nothing goes according to plan. Founders live day to day with a sense of uncertainty, isolation, and sometimes lack of progress. Plus, startups, by their nature, are doing new things — and when you do new things, people often reject you.

– Founders at Work, Jessica Livingston

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2009.12.26 Saturday ACHK

Transcender 1.2.1

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這段改編自 2010 年 3 月 20 日的對話。

我發覺我習慣了「transcend 掉」別人問我的問題。我往往不是直接回答,如何解決那個問題。我往往都是解釋,為何那個問題不重要,又或者,如何令到那個問題不再重要。

有時,「解決問題」的最好方法,未必是「直接解決」,而是把那個問題「transcend 掉」,令它不再重要。有時,只要宏觀一點看,原本的問題,會顯得無關痛癢。而真正的問題,就會立刻出現。解決真正的問題,往往會簡單和容易過,解決原本的問題。

例如,在太空中沒有引力。太空人不能用一般原子筆書寫。於是,美國人花了數以萬計的金錢,去研發一種,在太空中都可以使用的「太空原子筆」。但是,蘇聯人卻選用了鉛筆 -不費吹灰之力,就解決了真正的問題,避開了原本的問題。或者說,蘇聯人透過解決真正的問題,去避開了原本的問題。

真正的問題是「在太空中書寫」。原本的問題「在太空中用原子筆」,只是表面的問題,所以可以 transcend 掉。

(這個故事是虛構的,而且違反科學,但適合用作比喻。)

— Me@2012.04.03 

One of the most useful mental habits I know I learned from Michael Rabin: that the best way to solve a problem is often to redefine it.

The way to kill it is to redefine the problem as a superset of the current one.

— Paul Graham

2012.04.03 Tuesday (c) All rights reserved by ACHK

No-cloning theorem

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The no-cloning theorem is a result of quantum mechanics that forbids the creation of identical copies of an arbitrary unknown quantum state.

The state of one system can be entangled with the state of another system. For instance, one can use the Controlled NOT gate and the Walsh-Hadamard gate to entangle two qubits. This is not cloning. No well-defined state can be attributed to a subsystem of an entangled state. Cloning is a process whose end result is a separable state with identical factors.

Consequences

    The no-cloning theorem prevents us from using classical error correction techniques on quantum states. For example, we cannot create backup copies of a state in the middle of a quantum computation, and use them to correct subsequent errors. Error correction is vital for practical quantum computing, and for some time this was thought to be a fatal limitation. In 1995, Shor and Steane revived the prospects of quantum computing by independently devising the first quantum error correcting codes, which circumvent the no-cloning theorem.

    The no cloning theorem prevents us from viewing the holographic principle for black holes as meaning we have two copies of information lying at the event horizon and the black hole interior simultaneously. This leads us to more radical interpretations like black hole complementarity.

— Wikipedia on No-cloning theorem

2012.04.01 Sunday ACHK