in an echo-free chamber.

這就是全像球，一個不會產生回音的，

Think of the AlloSphere as a large,

三層樓高的金屬球狀內部空間。

dynamically varying digital microscope

你可以把全像球想像為一個大的、

that's connected to a supercomputer.

連接著超級電腦的

20 researchers can stand on a bridge

動態數位顯微鏡。

suspended inside of the sphere, and be

20 個研究員可以站在球體內

completely immersed in their data.

懸置的橋上，

Imagine if a team of physicists

完全地和他們的數據融為一體。

could stand inside of an atom

想像一下如果一組物理學家，

and watch and hear electrons spin.

可以站在原子裏面，

Imagine if a group of sculptors

並且可以看到、聽到電子的自旋。

could be inside of a lattice of atoms

想像一下如果一組雕塑家，

and sculpt with their material.

可以站在原子的矩陣內

Imagine if a team of surgeons could fly

並用他們的材料進行雕塑。

into the brain, as though it was a world,

想像一下如果一組外科醫生，可以

and see tissues as landscapes,

在大腦裏飛翔，就好像大腦內是另一個世界一樣，

and hear blood density levels as music.

將組織想像成地形景緻，

This is some of the research that you're going to see

將血液密度高低當成音樂來聽。

that we're undertaking at the AlloSphere.

這就是你們將看到的一部分

But first a little bit about this group

我們正在全像球裡進行的研究。

of artists, scientists, and engineers

但是先讓我介紹一下，

that are working together.

跟我們一起工作的藝術家、科學家和

I'm a composer, orchestrally-trained,

工程師小組。

and the inventor of the AlloSphere.

我是一個交響樂團的作曲家，

With my visual artist colleagues, we map

也是全像球的發明者。

complex mathematical algorithms that unfold in time and space,

跟我的視覺藝術家同事一起，我們利用

visually and sonically.

聲音與圖像繪出了各種

Our scientist colleagues are finding new patterns

在時間與空間中拓展的複雜數學演算法。

in the information.

我們的科學家同事正在

And our engineering colleagues are making

資訊裡尋找新的規律。

one of the largest dynamically varying computers in the world

而我們的工程師同事正在製造一個

for this kind of data exploration.

世界上最大的動態電腦，

I'm going to fly you into five research projects

以用於這種資料探索。

in the AlloSphere that are going to take you from

我將要帶你們飛進全像球

biological macroscopic data

裡的五個研究計畫，那將帶領你們從

all the way down to electron spin.

宏觀生物學數據

This first project is called the AlloBrain.

一路縮小到電子的自旋。

And it's our attempt to quantify beauty

第一個項目叫做全像大腦。

by finding which regions of the brain

這是我們試圖在找出大腦

are interactive while witnessing something beautiful.

和美麗事物互動區域的同時

You're flying through the cortex of my colleague's brain.

去量化美麗。

Our narrative here is real fMRI data

你們正在飛躍我一個同事的大腦皮層，

that's mapped visually and sonically.

我們在這裡所做的，是將真實的 fMRI 資料

The brain now a world that we can fly through and interact with.

以視覺和聽覺的方式顯現。

You see 12 intelligent computer agents,

現在大腦就像一個我們可以在其中飛翔並與之互動的世界。

the little rectangles that are flying in the brain with you.

你看到了 12 個智慧電腦媒介，

They're mining blood density levels.

就是那些和你一起在腦內飛翔的長方形，

And they're reporting them back to you sonically.

它們在探測血液密度的高低，

Higher density levels mean

然後它們通過聲音將狀態回報給你。

more activity in that point of the brain.

密度高表示著

They're actually singing these densities to you

大腦中那個部位較為活躍。

with higher pitches mapped to higher densities.

他們實際上正在將密度「唱」給你們聽，

We're now going to move from real biological data

愈高的音調代表著愈高的密度。

to biogenerative algorithms that create artificial nature

我們現在將要從真正的生物資料

in our next artistic and scientific installation.

移到創造人工自然的生物合成演算法，

In this artistic and scientific installation, biogenerative algorithms

我將在下一個藝術和科學的裝置中展現給你們。

are helping us to understand

在這個兼具藝術性和科學性的裝置中，生物合成演算法

self-generation and growth:

將要幫我們去瞭解

very important for simulation in the nanoscaled sciences.

自我繁殖和生長。

For artists, we're making new worlds

這是在奈米規模的科學上的一個十分重要的模擬。

that we can uncover and explore.

對藝術家而言，我們正在創造

These generative algorithms grow over time,

我們可以開拓和探索的新世界。

and they interact and communicate as a swarm of insects.

就在這些自我生長演算法在成長的同時，

Our researchers are interacting with this data

他們就像一群昆蟲一樣地在互動和交流。

by injecting bacterial code,

我們的研究員通過注入細菌代碼

which are computer programs,

去和這個數據互動，

that allow these creatures to grow over time.

那些都是允許讓這些生物

We're going to move now from the biological

不停成長的電腦程式。

and the macroscopic world,

我們現在要從這個生物性的

down into the atomic world,

宏觀世界

as we fly into a lattice of atoms.

深入到原子的世界，

This is real AFM -- Atomic Force Microscope -- data

現在我們正在飛往原子的矩陣中。

from my colleagues in the Solid State Lighting and Energy Center.

這是真正的 AFM，原子力顯微鏡資料，

They've discovered a new bond,

這些資料來自於我在固態光學暨能源中心的同事。

a new material for transparent solar cells.

他們已經發現了一個新的化學鍵，

We're flying through 2,000 lattice of atoms --

一種可以應用到透明太陽能電池的新材料。

oxygen, hydrogen and zinc.

我們正在飛躍二千個原子的矩陣 --

You view the bond in the triangle.

氧、氫和鋅。

It's four blue zinc atoms

你看到了這個三角形的化學鍵。

bonding with one white hydrogen atom.

這是四個藍色的鋅原子

You see the electron flow with the streamlines

和一個白色的氫原子鍵結在一起。

we as artists have generated for the scientists.

你們看到了這些帶著流線型軌跡的電子流，

This is allowing them to find the bonding nodes in any lattice of atoms.

這是作為藝術家的我們為科學家們所設計的。

We think it makes a beautiful structural art.

這可以讓他們在任何原子矩陣中去尋找鍵結的節點。

The sound that you're hearing are the actual

我們認為這是一個美麗的結構藝術。

emission spectrums of these atoms.

你們現在聽到的聲音實際上是

We've mapped them into the audio domain,

這些原子的放射光譜。

so they're singing to you.

我們將它們對應到聲音的頻帶中。

Oxygen, hydrogen and zinc have their own signature.

所以它們就在對你們唱歌。

We're going to actually move even further down

氧、氫和鋅有它們自己的特徵。

as we go from this lattice of atoms

我們甚至可以更深入一點，

to one single hydrogen atom.

從這個原子矩陣

We're working with our physicist colleagues

到一個單獨的氫原子。

that have given us the mathematical calculations

我們和物理學的同事一起工作，

of the n-dimensional Schrödinger equation in time.

他們為我們解出「三度空間中與時間相關的

What you're seeing here right now is a superposition of an electron

薛丁格方程式」。

in the lower three orbitals of a hydrogen atom.

現在你們看到的是，在氫原子裡

You're actually hearing and seeing the electron flow with the lines.

三個低階電子軌域的混成軌域。

The white dots are the probability wave

你們可以聽到和看到這些帶著軌跡的電子流動情形，

that will show you where the electron is

白色的點是概率波，

in any given point of time and space

它告訴你在任何一個時空中，

in this particular three-orbital configuration.

在這特殊的三軌域組態中

In a minute we're going to move to a two-orbital configuration,

電子的所在位置。

and you're going to notice a pulsing.

一會兒後我們將要移至兩個軌域的組態，

And you're going to hear an undulation between the sound.

然後你將會注意到一個脈衝。

This is actually a light emitter.

然後你會聽到一個波動的聲音，

As the sound starts to pulse and contract,

這實際上是一個放射光子。

our physicists can tell when a photon is going to be emitted.

當這聲音開始脈衝然後收縮，

They're starting to find new mathematical structures

我們的物理學家可以得知，何時光子將被放射。

in these calculations.

他們開始在這些計算中找到

And they're understanding more about quantum mathematics.

新的數學結構。

We're going to move even further down,

然後他們就會更加瞭解量子數學。

and go to one single electron spin.

我們要繼續深入，

This will be the final project that I show you.

去看看單個電子的自旋。

Our colleagues in the Center for Quantum Computation

這將是我為你們展示的最後一個計畫。

and Spintronics are actually measuring with their lasers

我們在量子計算研究中心和自旋電子學

decoherence in a single electron spin.

的同事，通過雷射去

We've taken this information and we've

測量電子的環繞。

made a mathematical model out of it.

我們取得這些資料，然後

You're actually seeing and hearing

我們用它做出了一個數學模型。

quantum information flow.

你們現在看到和聽到的是

This is very important for the next step in simulating

量子資訊流。

quantum computers and information technology.

這對於接下來模擬量子電腦和資訊科技

So these brief examples that I've shown you

是十分重要的一步。

give you an idea of the kind of work that we're doing

好了，這些是我為你們展示的小例子，

at the University of California, Santa Barbara,

讓你們對於我們在加州大學

to bring together, arts, science

聖塔芭芭拉分校的工作有個概念，

and engineering

是將藝術、科學

into a new age of math, science and art.

和工程學混合在一起，

We hope that all of you will come to see the AlloSphere.

創造出一個數學、科學和藝術的新領域。

Inspire us to think of new ways that we can use

我們希望你們都能來參觀全像球。

this unique instrument that we've created at Santa Barbara.

來啟發我們思考對於我們在聖塔芭芭拉

Thank you very much.

所創造的這個獨特的新儀器能有什麼全新的應用。

(Applause)

十分感謝。