臺灣博碩士論文加值系統

本研究提出以腦波特徵頻帶進行方向辨識應用之探討。實驗透過腦波感測器擷取人體視覺在感測代表方向之箭頭測試介面時之腦波訊號，並經統計分析腦波特徵頻帶的能量分佈後，訂定代表往上、往下等方向之腦波特徵頻帶。研究根據此腦波特徵頻帶的分佈，計算遊戲中移動方向的專注力值，並與電腦虛擬玩家進行方向控制的競賽。研究實驗透過方向箭頭測試介面進行方向辨識的腦波訊號擷取與分析，並據此建立具方向辨識功能的腦波特徵頻帶。本研究除了針對受測者在進行方向辨識時所呈現的各種腦波頻帶特徵進行分析探討外，並以認知神經科學的觀點訂定腦波在進行方向辨識時的專注力計算式。

This research discusses about direction recognition by characteristic frequency bands of brainwave. This experiences proceeded by catching brain wave signals of human vision while sensing the test interfaces of arrows representing direction by brain wave sensor. To compile the related samples of energies from brainwave frequency band, then establish the directions which stand for forward and backward of brainwave characteristics frequency band. The experiments catch and analyze brain wave signals from by brain-wave sensor, and then calculate the attention value of direction recognition to control the movement of direction. This research not only analyzed and discussed every kind of brain wave frequency band characteristics while subjects recognize the directions, but also proposed the formula to calculate the value of attention controlling the movement of direction in the view of Cognitive Neuroscience.

第一章 緒論
1.1 前言
1.2 研究動機
1.3 研究目的
1.4 論文結構
第二章 認知神經科學
2.1 認知神經科學概述
2.2 認知神經科學之生理結構基礎
2.3 認知神經科學之應用
2.4 腦波簡介
2.5 腦波應用
2.5.1 醫療的運用
2.5.2 腦波之遊戲設計應用
第三章 EEG量測模組設計
3.1 腦波量測之電路方塊圖
3.1.1 前置放大器
3.1.2 隔離電路設計
3.1.3 帶通濾波器電路設計
3.1.4 增益放大器
3.1.5 USB-6009資料擷取卡
3.2 LabVIEW腦波擷取界面
第四章 腦波辨識的方向控制遊戲設計
4.1 系統架構分析
4.2 腦波訊號分析方法
4.2.1 快速傅立葉轉換(FFT)
4.2.2 事件關聯連貫性數值(ERCoh)
4.3 方向測試介面之腦波訊號量測
4.3.1 腦波方向辨識之遊戲介面
4.3.2 方向控制之腦波遊戲實作
第五章 結論
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