《智能仪器》课程设计
题 目: MATLAB实现语音识别功能
目录
设计任务及要求1
语音识别的简单介绍
2.1语者识别的概念2
2.2特征参数的提取3
2.3用矢量量化聚类法生成码本3
2.4VQ的说话人识别 4
算法程序分析
3.1函数关系.4
3.2代码说明5
3.2.1函数mfcc5
3.2.2函数disteu5
3.2.3函数vqlbg.6
3.2.4函数test6
3.2.5函数testDB7
3.2.6 函数train8
3.2.7函数melfb8
演示分析.9
心得体会.11
附:GUI程序代码12
用MATLAB实现简单的语音识别功能; 具体设计要求如下: 用MATLAB实现简单的数字1~9的语音识别功能。 基于VQ的说话人识别系统,矢量量化起着双重作用。在训练阶段,把每一个说话者所提取的特征参数进行分类,产生不同码字所组成的码本。在识别(匹配)阶段,我们用VQ方法计算平均失真测度(本系统在计算距离d时,采用欧氏距离测度),从而判断说话人是谁。 语音识别系统结构框图如图1所示。 图1 语音识别系统结构框图 2.1语者识别的概念 语者识别就是根据说话人的语音信号来判别说话人的身份。语音是人的自然属性之一,由于说话人发音器官的生理差异以及后天形成的行为差异,每个人的语音都带有强烈的个人色彩,这就使得通过分析语音信号来识别说话人成为可能。用语音来鉴别说话人的身份有着许多独特的优点,如语音是人的固有的特征,不会丢失或遗忘;语音信号的采集方便,系统设备成本低;利用电话网络还可实现远程客户服务等。因此,近几年来,说话人识别越来越多的受到人们的重视。与其他生物识别技术如指纹识别、手形识别等相比较,说话人识别不仅使用方便,而且属于非接触性,容易被用户接受,并且在已有的各种生物特征识别技术中,是唯一可以用作远程验证的识别技术。因此,说话人识别的应用前景非常广泛:今天,说话人识别技术已经关系到多学科的研究领域,不同领域中的进步都对说话人识别的发展做出了贡献。说话人识别技术是集声学、语言学、计算机、信息处理和人工智能等诸多领域的一项综合技术,应用需求将十分广阔。在吃力语音信号的时候如何提取信号中关键的成分尤为重要。语音信号的特征参数的好坏直接导致了辨别的准确性。 2.2特征参数的提取 对于特征参数的选取,我们使用mfcc的方法来提取。MFCC参数是基于人的听觉特性利用人听觉的屏蔽效应,在Mel标度频率域提取出来的倒谱特征参数。 MFCC参数的提取过程如下: - 1. 对输入的语音信号进行分帧、加窗,然后作离散傅立叶变换,获得频谱分布信息。
设语音信号的DFT为:  (1) 其中式中x(n)为输入的语音信号,N表示傅立叶变换的点数。 - 2. 再求频谱幅度的平方,得到能量谱。
- 3. 将能量谱通过一组Mel尺度的三角形滤波器组。
我们定义一个有M个滤波器的滤波器组(滤波器的个数和临界带的个数相近),采用的滤波器为三角滤波器,中心频率为f(m),m=1,2,3,···,M 本系统取M=100。  (2)其中  为三角滤波器的频率响应。 MFCC系数个数通常取20—30,常常不用0阶倒谱系数,因为它反映的是频谱能量,故在一般识别系统中,将称为能量系数,并不作为倒谱系数,本系统选取20阶倒谱系数。
2.3用矢量量化聚类法生成码本 我们将每个待识的说话人看作是一个信源,用一个码本来表征。码本是从该说话人的训练序列中提取的MFCC特征矢量聚类而生成。只要训练的序列足够长,可认为这个码本有效地包含了说话人的个人特征,而与讲话的内容无关。 本系统采用基于分裂的LBG的算法设计VQ码本,  为训练序列,B为码本。 具体实现过程如下: - 1. 取提取出来的所有帧的特征矢量的型心(均值)作为第一个码字矢量B1。
- 2. 将当前的码本Bm根据以下规则分裂,形成2m个码字。
 (4)
其中m从1变化到当前的码本的码字数,ε是分裂时的参数,本文ε=0.01。 - 3. 根据得到的码本把所有的训练序列(特征矢量)进行分类,然后按照下面两个公式计算训练矢量量化失真量的总和
 以及相对失真(n为迭代次数,初始n=0, =∞,B为当前的码书),若相对失真小于某一阈值ε,迭代结束,当前的码书就是设计好的2m个码字的码书,转5。否则,转下一步。
量化失真量和:  (5) 相对失真:  (6) 4. 重新计算各个区域的新型心,得到新的码书,转3。 5. 重复2 ,3 和4步,直到形成有M个码字的码书(M是所要求的码字数),其中D0=10000。
2.4 VQ的说话人识别 设是未知的说话人的特征矢量  ,共有T帧是训练阶段形成的码书,表示码书第m个码字,每一个码书有M个码字。再计算测试者的平均量化失真D,并设置一个阈值,若D小于此阈值,则是原训练者,反之则认为不是原训练者。  (7) 在具体的实现过程当中,采用了matlab软件来帮助完成这个项目。在matlab中主要由采集,分析,特征提取,比对几个重要部分。以下为在实际的操作中,具体用到得函数关系和作用一一列举在下面。 3.1函数关系 主要有两类函数文件Train.m和Test.m 在Train.m调用Vqlbg.m获取训练录音的vq码本,而[url=]Vqlbg.m调用mfcc.m获取单个录音的mel倒谱系数[/url],接着mfcc.m调用Melfb.m---将能量谱通过一组Mel尺度的三角形滤波器组。 在Test.m函数文件中调用Disteu.m计算训练录音(提供vq码本)与测试录音(提供mfcc)mel倒谱系数的距离,即判断两声音是否为同一录音者提供。[url=]Disteu.m调用mfcc.m获取单个录音的mel倒谱系数[/url]。mfcc.m调用Melfb.m---将能量谱通过一组Mel尺度的三角形滤波器组。 3.2具体代码说明 3.2.1函数mffc: function r = mfcc(s, fs) --- m = 100; n = 256; l = length(s); nbFrame = floor((l - n) / m) + 1; %沿-∞方向取整 for i = 1:n for j = 1:nbFrame M(i, j) = s(((j - 1) * m) + i); %对矩阵M赋值 end end h = hamming(n); %加 hamming 窗,以增加音框左端和右端的连续性 M2 = diag(h) * M; for i = 1:nbFrame frame(:,i) = fft(M2(:, i)); %对信号进行快速傅里叶变换FFT end t = n / 2; tmax = l / fs; m = melfb(20, n, fs); %将上述线性频谱通过Mel 频率滤波器组得到Mel 频谱,下面在将其转化成对数频谱 n2 = 1 + floor(n / 2); z = m * abs(frame(1:n2, :)).^2; r = dct(log(z)); %将上述对数频谱,经过离散余弦变换(DCT)变换到倒谱域,即可得到Mel 倒谱系数(MFCC参数) 3.2.2函数disteu ---计算测试者和模板码本的距离 function d = disteu(x, y)
[M, N] = size(x); %音频x赋值给【M,N】 [M2, P] = size(y); %音频y赋值给【M2,P】 if (M ~= M2) error('不匹配!') %两个音频时间长度不相等 end d = zeros(N, P); if (N < P)%在两个音频时间长度相等的前提下 copies = zeros(1,P); for n = 1:N d(n,:) = sum((x(:, n+copies) - y) .^2, 1); end else copies = zeros(1,N); for p = 1:P d(:,p) = sum((x - y(:, p+copies)) .^2, 1)'; end%%成对欧氏距离的两个矩阵的列之间的距离 end d = d.^0.5; 3.2.3函数vqlbg ---该函数利用矢量量化提取了音频的vq码本 function r = vqlbg(d,k) e = .01; r = mean(d, 2); dpr = 10000; for i = 1:log2(k) r = [r*(1+e), r*(1-e)]; while (1 == 1) z = disteu(d, r); [m,ind] = min(z, [], 2); t = 0; for j = 1:2^i r(:, j) = mean(d(:, find(ind == j)), 2); x = disteu(d(:, find(ind == j)), r(:, j)); for q = 1:length(x) t = t + x(q); end end if (((dpr - t)/t) < e) break; else dpr = t; end end end 3.2.4函数test function finalmsg = test(testdir, n, code)
for k = 1:n % read test sound file of each speaker file = sprintf('%ss%d.wav', testdir, k); [s, fs] = wavread(file);
v = mfcc(s, fs); % 得到测试人语音的mel倒谱系数 distmin = 4; %阈值设置处 % 就判断一次,因为模板里面只有一个文件 d = disteu(v, code{1}); %计算得到模板和要判断的声音之间的“距离” dist = sum(min(d,[],2)) / size(d,1); %变换得到一个距离的量
%测试阈值数量级 msgc = sprintf('与模板语音信号的差值为:%10f ', dist); disp(msgc); %此人匹配
if dist <= distmin %一个阈值,小于阈值,则就是这个人。 msg = sprintf('第%d位说话者与模板语音信号匹配,符合要求!\n', k); finalmsg = '此位说话者符合要求!'; %界面显示语句,可随意设定 disp(msg); end %此人不匹配
if dist > distmin msg = sprintf('第%d位说话者与模板语音信号不匹配,不符合要求!\n', k); finalmsg = '此位说话者不符合要求!'; %界面显示语句,可随意设定 disp(msg); end end
3.2.5函数testDB 这个函数实际上是对数据库一个查询,根据测试者的声音,找相应的文件,并且给出是谁的提示 function testmsg = testDB(testdir, n, code) nameList={'1','2','3','4','5','6','7','8','9' }; %这个是我们要识别的9个数 for k = 1:n % 数据库中每一个说话人的特征 file = sprintf('%ss%d.wav', testdir, k); %找出文件的路径 [s, fs] = wavread(file);
v = mfcc(s, fs); % 对找到的文件取mfcc变换 distmin = inf; k1 = 0;
for l = 1:length(code) d = disteu(v, code{l}); dist = sum(min(d,[],2)) / size(d,1);
if dist < distmin distmin = dist;%%这里和test函数里面一样 但多了一个具体语者的识别 k1 = l; end end msg=nameList{k1} msgbox(msg); end
3.2.6 函数train ---该函数就是对音频进行训练,也就是提取特征参数 function code = train(traindir, n)
k = 16; % number of centroids required for i = 1:n % 对数据库中的代码形成码本 file = sprintf('%ss%d.wav', traindir, i); disp(file); [s, fs] = wavread(file); v = mfcc(s, fs); % 计算 MFCC's 提取特征特征,返回值是Mel倒谱系数,是一个log的dct得到的 code{i} = vqlbg(v, k); % 训练VQ码本 通过矢量量化,得到原说话人的VQ码本 end 3.2.7 函数melfb ---确定矩阵的滤波器 function m = melfb(p, n, fs)
f0 = 700 / fs; fn2 = floor(n/2); lr = log(1 + 0.5/f0) / (p+1); % convert to fft bin numbers with 0 for DC term bl = n * (f0 * (exp([0 1 p p+1] * lr) - 1)); 直接转换为FFT的数字模型 b1 = floor(bl(1)) + 1; b2 = ceil(bl(2)); b3 = floor(bl(3)); b4 = min(fn2, ceil(bl(4))) - 1; pf = log(1 + (b1:b4)/n/f0) / lr; fp = floor(pf); pm = pf - fp;
r = [fp(b2:b4) 1+fp(1:b3)]; c = [b2:b4 1:b3] + 1; v = 2 * [1-pm(b2:b4) pm(1:b3)]; m = sparse(r, c, v, p, 1+fn2);
我们的功能分为两部分:对已经保存的9个数字的语音进行辨别和实时的判断说话人说的是否为一个数.在前者的实验过程中,先把9个数字的声音保存成wav的格式,放在一个文件夹中,作为一个检测的数据库.然后对检测者实行识别,系统给出提示是哪个数字. 在第二个功能中,实时的录取一段说话人的声音作为模板,提取mfcc特征参数,随后紧接着进行遇着识别,也就是让其他人再说相同的话,看是否是原说话者.
实验过程及具体功能如下: 先打开Matlab 使Current Directory为录音及程序所所在的文件夹 再打开文件“enter.m”,点run运行,打开enter界面,点击“进入”按钮进入系统。(注:文件包未封装完毕,目前只能通过此方式打开运行。)(如下图figure1) figure1 在对数据库中已有的语者进行识别模块: 选择载入语音库语音个数; 点击语音库录制模版进行已存语音信息的提取; 点击录音-test进行现场录音; 点击语者判断进行判断数字,并显示出来。 在实时语者识别模块: 点击实时录制模板上的“录音-train”按钮,是把新语者的声音以wav格式存放在”实时模板”文件夹中, 接着点击“实时录制模板”,把新的模板提取特征值。随后点击实时语者识别模板上的“录音-train”按钮,是把语者的声音以wav格式存放在”测试”文件夹中,再点击“实时语者识别”,在对测得的声音提取特征值的同时,和实时模板进行比对,然后得出是否是实时模板中的语者。另外面板上的播放按钮都是播放相对应左边录取的声音。 想要测量多次,只要接着录音,自动保存,然后程序比对音频就可以。 退出只要点击菜单File/Exit,退出程序。 程序运行截图: (fig.2)运行后系统界面 实验表明,该系统能较好地进行语音的识别,同时,基于矢量量化技术 (VQ)的语音识别系统具有分类准确,存储数据少,实时响应速度快等综合性能好的特点. 矢量量化技术在语音识别的应用方面,尤其是在孤立词语音识别系统中得到很好的应用,特别是有限状态矢量量化技术,对于语音识别更为有效。 通过这次课程设计,我对语音识别有了更加形象化的认识,也强化了MATLAB的应用,对将来的学习奠定了基础。 附:GUI程序代码
- function varargout = untitled2(varargin)
- % UNTITLED2 M-file for untitled2.fig
- % UNTITLED2, by itself, creates a new UNTITLED2 or raises the existing
- % singleton*.
- %
- % H = UNTITLED2 returns the handle to a new UNTITLED2 or the handle to
- % the existing singleton*.
- %
- % UNTITLED2('CALLBACK',hObject,eventData,handles,...) calls the local
- % function named CALLBACK in UNTITLED2.M with the given input arguments.
- %
- % UNTITLED2('Property','Value',...) creates a new UNTITLED2 or raises the
- % existing singleton*. Starting from the left, property value pairs are
- % applied to the GUI before untitled2_OpeningFunction gets called. An
- % unrecognized property name or invalid value makes property application
- % stop. All inputs are passed to untitled2_OpeningFcn via varargin.
- %
- % *See GUI Options on GUIDE's Tools menu. Choose "GUI allows only one
- % instance to run (singleton)".
- %
- % See also: GUIDE, GUIDATA, GUIHANDLES
-
- % Copyright 2002-2003 The MathWorks, Inc.
-
- % Edit the above text to modify the response to help untitled2
-
- % Last Modified by GUIDE v2.5 08-Jun-2010 23:58:57
- % Begin initialization code - DO NOT EDIT
- gui_Singleton = 1;
- gui_State = struct('gui_Name', mfilename, ...
- 'gui_Singleton', gui_Singleton, ...
- 'gui_OpeningFcn', @untitled2_OpeningFcn, ...
- 'gui_OutputFcn', @untitled2_OutputFcn, ...
- 'gui_LayoutFcn', [] , ...
- 'gui_Callback', []);
- if nargin && ischar(varargin{1})
- gui_State.gui_Callback = str2func(varargin{1});
- end
- if nargout
- [varargout{1:nargout}] = gui_mainfcn(gui_State, varargin{:});
- else
- gui_mainfcn(gui_State, varargin{:});
- end
- % End initialization code - DO NOT EDIT
- % --- Executes just before untitled2 is made visible.
- function untitled2_OpeningFcn(hObject, eventdata, handles, varargin)
- % This function has no output args, see OutputFcn.
- % hObject handle to figure
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- % varargin command line arguments to untitled2 (see VARARGIN)
- % Choose default command line output for untitled2
- handles.output = hObject;
- % Update handles structure
- guidata(hObject, handles);
- axes(findobj('tag','axes13'));
- imshow('3.jpg');
- axes(findobj('tag','axes12'));
- imshow('1.jpg');
- % UIWAIT makes untitled2 wait for user response (see UIRESUME)
- % uiwait(handles.figure1);
- % --- Outputs from this function are returned to the command line.
- function varargout = untitled2_OutputFcn(hObject, eventdata, handles)
- % varargout cell array for returning output args (see VARARGOUT);
- % hObject handle to figure
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- % Get default command line output from handles structure
- varargout{1} = handles.output;
- % --- Executes on button press in pushbutton1.
- function pushbutton1_Callback(hObject, eventdata, handles)
- % hObject handle to pushbutton1 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- Channel_Str=get(handles.popupmenu3,'String');
- Channel_Number=str2double(Channel_Str{get(handles.popupmenu3,'Value')});
- global moodle;
- moodle = train('模版\',Channel_Number) %??′y?óó?ò???DDìáè???±?
- % --- Executes on button press in pushbutton2.
- function pushbutton2_Callback(hObject, eventdata, handles)
- % hObject handle to pushbutton2 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handglobal data1;
- global moodle ;
- test('测试\',1,moodle)%êμê±ó?ò??ì2a
- % --------------------------------------------------------------------
- function Open_Callback(hObject, eventdata, handles)
- % hObject handle to Open (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- [filename,pathname]=uigetfile('')
- file=get(handles.edits,[filename,pathname])
- [y,f,b]=wavread(file);
- % --------------------------------------------------------------------
- function Exit_Callback(hObject, eventdata, handles)
- % hObject handle to Exit (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- exit
- % --------------------------------------------------------------------
- function About_Callback(hObject, eventdata, handles)
- % hObject handle to About (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- H=['语者识别']
- helpdlg(H,'help text')
- % --------------------------------------------------------------------
- function File_Callback(hObject, eventdata, handles)
- % hObject handle to File (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- % --------------------------------------------------------------------
- function Edit_Callback(hObject, eventdata, handles)
- % hObject handle to Edit (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- % --------------------------------------------------------------------
- function Help_Callback(hObject, eventdata, handles)
- % hObject handle to Help (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- % --- Executes on button press in pushbutton7.
- function pushbutton7_Callback(hObject, eventdata, handles)
- % hObject handle to pushbutton7 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- msg='请速度录音?'
- msgbox(msg)
- clear
- global data1;
- %global dataDN1;
- AI = analoginput('winsound');
- chan = addchannel(AI,1:2);
- duration = 3; %1 second acquisition
- set(AI,'SampleRate',8000)
- ActualRate = get(AI,'SampleRate');
- set(AI,'SamplesPerTrigger',duration*ActualRate)
- set(AI,'TriggerType','Manual')
- blocksize = get(AI,'SamplesPerTrigger');
- Fs = ActualRate;
- start(AI)
- trigger(AI)
- [data1,time,abstime,events] = getdata(AI);
- fname=sprintf('E:\\Matlab语音识别系统\\实时模版\\s1.wav')
- %dataDN1=wden(data1,'heursure','s','one',5,'sym8');denoise
- wavwrite(data1,fname)
- msgbox(fname)
- % --- Executes on button press in pushbutton8.
- function pushbutton8_Callback(hObject, eventdata, handles)
- % hObject handle to pushbutton8 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- global data1;
- %global dataDN1;
- sound(data1)
- %sound(dataDN1)
- axes(handles.axes1)%set to plot at axes1
- plot(data1);
- %plot(dataDN1);
- xlabel('训练采样序列'),ylabel('信号幅');
- %xlabel('?μá·2é?ùDòáD'),ylabel('sym8D?2¨?μ??oóμ?D?o?·ù');
- grid on;
- clear
- % --- Executes on button press in pushbutton9.
- function pushbutton9_Callback(hObject, eventdata, handles)
- % hObject handle to pushbutton9 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- msg='请速度录音?'
- msgbox(msg)
- clear
- global data2;
- %global dataDN2;
- AI = analoginput('winsound');
- chan = addchannel(AI,1:2);
- duration = 3; %1 second acquisition
- set(AI,'SampleRate',8000)
- ActualRate = get(AI,'SampleRate');
- set(AI,'SamplesPerTrigger',duration*ActualRate)
- set(AI,'TriggerType','Manual')
- blocksize = get(AI,'SamplesPerTrigger');
- Fs = ActualRate;
- start(AI)
- trigger(AI)
- [data2,time,abstime,events] = getdata(AI);
- fname=sprintf('E:\\Matlab语音识别系统\\测试\\s1.wav')
- %dataDN1=wden(data1,'heursure','s','one',5,'sym8');denoise
- wavwrite(data2,fname)
- msgbox(fname)
- % --- Executes on button press in pushbutton10.
- function pushbutton10_Callback(hObject, eventdata, handles)
- % hObject handle to pushbutton10 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- global data2;
- %global dataDN2;
- sound(data2)
- %sound(dataDN2)
- axes(handles.axes2)%set to plot at axes1
- plot(data2);
- %plot(dataDN2);
- xlabel('测试采样序列'),ylabel('信号幅');
- %xlabel('2aê?2é?ùDòáD'),ylabel('sym8D?2¨?μ??oóμ?D?o?·ù');%%
- grid on;
- clear
- % --- Executes on button press in pushbutton11.
- function pushbutton11_Callback(hObject, eventdata, handles)
- % hObject handle to pushbutton11 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- global moodle ;
- testDB('测试\',1,moodle)
- % --- Executes on button press in pushbutton12.
- function pushbutton12_Callback(hObject, eventdata, handles)
- % hObject handle to pushbutton12 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- global moodle;
- moodle = train('实时模板\',1)
- % --- Executes on selection change in popupmenu3.
- function popupmenu3_Callback(hObject, eventdata, handles)
- % hObject handle to popupmenu3 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- % Hints: contents = get(hObject,'String') returns popupmenu3 contents as cell array
- % contents{get(hObject,'Value')} returns selected item from popupmenu3
- str=get(handles.popupmenu3,'String');
- val=str2num(str{get(handles.popupmenu3,'Value')});
- switch val
- case 1
- case 2
- case 3
- case 4
- case 5
- case 6
- case 7
- case 8
- case 9
- end
- % --- Executes during object creation, after setting all properties.
- function popupmenu3_CreateFcn(hObject, eventdata, handles)
- % hObject handle to popupmenu3 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles empty - handles not created until after all CreateFcns called
- % Hint: popupmenu controls usually have a white background on Windows.
- % See ISPC and COMPUTER.
- if ispc && isequal(get(hObject,'BackgroundColor'), get(0,'defaultUicontrolBackgroundColor'))
- set(hObject,'BackgroundColor','white');
- end
- % --- Executes on button press in pushbutton9.
- function pushbutton13_Callback(hObject, eventdata, handles)
- % hObject handle to pushbutton9 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- % --- Executes on button press in pushbutton10.
- function pushbutton14_Callback(hObject, eventdata, handles)
- % hObject handle to pushbutton10 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles structure with handles and user data (see GUIDATA)
- % --- Executes during object creation, after setting all properties.
- %function axes8_CreateFcn(hObject, eventdata, handles)
- % hObject handle to axes8 (see GCBO)
- % eventdata reserved - to be defined in a future version of MATLAB
- % handles empty - handles not created until after all CreateFcns called
-
- % Hint: place code in OpeningFcn to populate axes8
-
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