基於演算法之絲狀微生物仿生動畫技術創作研究

隨著三維動畫技術和演算法設計的進步，將這些技術應用於藝術創作提供了無限可能。本創作除了聚焦於傳統的仿生學觀點，還有探索如何通過實驗性動畫技術，創造出反映絲狀微生物生長過程的視覺表現。受到演算法藝術家Andy Lomas在《Cellular Forms》中對細胞形態學藝術探索的啟發，本創作通過結合自然界的生長模式與數學演算法，以及利用三維動畫技術，來探索和呈現絲狀微生物的多樣化生長樣態及其生理機制。
本創作動畫專注於開發和應用實驗性演算法，模擬絲狀微生物的生長方式和形態變化，從而揭示其背後的隨機性和規律性。本創作的目的是透過創新的技術手段，提供一種新的視角來觀察和理解微觀生命的複雜性，同時為動畫技術創作、生物學研究及其他相關領域提供實驗性的探索工具。
本創作強調以圓點供給養分驅使微生物生長的實驗性動畫技術，探索自然界微觀生命形態中的應用，並探討這些技術如何幫助我們以另一種方式模擬微生物生長的方式，以及透過模擬基礎的生長方式而非預先設定模型的最終形態，讓動畫中的微生物自然演化至最終的自然形狀。本創作的方法揭示出生長過程中的不可預測性和多樣性。

With the advancement of three-dimensional animation technologies and algorithm design, applying these technologies in artistic creation has opened up limitless possibilities. This work focuses not only on the traditional perspective of bionics but also explores how experimental animation techniques can be used to create visual representations of the growth process of filamentous microorganisms. Inspired by the algorithmic art exploration of cellular morphology by Andy Lomas in "Cellular Forms," this creation combines natural growth patterns with mathematical algorithms and utilizes three-dimensional animation technology to explore and present the diverse growth forms and physiological mechanisms of filamentous microorganisms.
This animated creation focuses on developing and applying experimental algorithms to simulate the growth modes and morphological changes of filamentous microorganisms, thereby revealing the underlying randomness and regularity. The purpose of this work is to provide a new perspective for observing and understanding the complexity of microscopic life through innovative technical means, while offering experimental exploration tools for animation technology creation, biological research, and other related fields.
This work emphasizes the experimental animation technique of driving microbial growth through the supply of nutrients at focal points, exploring its application in the natural micro-life forms, and discussing how these techniques help us simulate microbial growth in another way. By simulating the fundamental modes of growth rather than pre-setting the final form of the model, the microorganisms in the animation naturally evolve into their final natural shapes. This approach reveals the unpredictability and diversity in the growth process.