【数字信号调制】基于matlab GUI PCM编码调制【含Matlab源码 1018期】

一、获取代码方式

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二、PCM简介

数字信号是对连续变化的模拟信号进行抽样、量化和编码产生的，称为PCM（Pulse Code Modulation），即脉冲编码调制。

脉冲编码调制就是把一个时间连续，取值连续的模拟信号变换成时间离散，取值离散的数字信号后在信道中传输。脉冲编码调制就是对模拟信号先抽样，再对样值幅度量化，编码的过程。

抽样，就是对模拟信号进行周期性扫描，把时间上连续的信号变成时间上离散的信号。该模拟信号经过抽样后还应当包含原信号中所有信息，也就是说能无失真的恢复原模拟信号。它的抽样速率的下限是由抽样定理确定的。抽样速率采用8Kbit/s。

量化，就是把经过抽样得到的瞬时值将其幅度离散，即用一组规定的电平，把瞬时抽样值用最接近的电平值来表示。

一个模拟信号经过抽样量化后，得到已量化的脉冲幅度调制信号，它仅为有限个数值。

编码，就是用一组二进制码组来表示每一个有固定电平的量化值。然而，实际上量化是在编码过程中同时完成的，故编码过程也称为模/数变换，可记作A/D。

话音信号先经防混叠低通滤波器，进行脉冲抽样，变成8KHz重复频率的抽样信号（即离散的脉冲调幅PAM信号），然后将幅度连续的PCM信号用“四舍五入”办法量化为有限个幅度取值的信号，再经编码后转换成二进制码。对于电话，CCITT规定抽样率为8KHz，每抽样值编8位码，即共有2^8=256个量化值，因而每话路PCM编码后的标准数码率是64kb/s。为解决均匀量化时小信号量化误差大，音质差的问题，在实际中采用不均匀选取量化间隔的非线性量化方法，即量化特性在小信号时分层密，量化间隔小，而在大信号时分层疏，量化间隔大。

均匀量化的小信号的信噪比小。

非均匀量化: 由于一些信源信号, 如语音信号, 小幅度信号发生的概率大于大幅度信号的概率, 采用非均匀量化(即小幅度信号的量化步长小于大幅度信号的的量化步长) 效果更好好 (表现在语音信号上, 可以使信号具有足够的信噪比)。

非均匀量化特性通常是把信号通过一个非线性的设备, 小信号幅度进行放大, 大信号幅度进行压缩, 再通过均匀量化实现。

三、部分源代码

function varargout = PCM(varargin)% PCM M-file for PCM.fig%PCM was designed in order to show how PCM works%%To simplify the undesrtanding of this method, the program first takes%a sine wave. Then you can choose a sampling scheme, and you can see%the output of the sampler. You can choose one out of three sampling %methods.%If you choose natural sampling; then you will have the chance to modify%the sampling window, and see the effects of this change in the output of%the sampler.%%Once you got the sampled signal you can quantize it by a method that is %known as two rules and an alorithm.%The option Squeezing and Stretching shows the best G(x) tha minimizes %the MSE. You can better understand this using the book%Telecommunications Demystified written by Carl Nassar. You can find%information about this on Chapter four of that book. %You can edit the bit's number and the number of iterations of the%algorithm. The bigger the number of bits, the smaller the MSE.%The picture shows the signal after quantization, the first iteration%in the quantization process and the output of the quantizer%%Then, by pressing the Bit Stream button you will see the PCM output%of the signal that you have selected in the input area.%%Everytime you change something, you must push the button that is%related with the change you have just made. For example if don't%want to work anymore with the sine wave and you choose the random%signal, then you have to push the plot button in order to see the%plot of the random signal, and if you change of sampling method you%have to push the sampling button, when you changhe the sampling %window. So if you change the number of codewords or the number of %the iterations you will have to press the quantize button again. % Edit the above text to modify the response to help PCM% Last Modified by GUIDE v2.5 14-Mar- 12:32:35% Begin initialization code - DO NOT EDITgui_Singleton = 1;gui_State = struct('gui_Name', mfilename, ...'gui_Singleton', gui_Singleton, ...'gui_OpeningFcn', @PCM_OpeningFcn, ...'gui_OutputFcn', @PCM_OutputFcn, ...'gui_LayoutFcn', [] , ...'gui_Callback', []);if nargin && ischar(varargin{1})gui_State.gui_Callback = str2func(varargin{1});endif nargout[varargout{1:nargout}] = gui_mainfcn(gui_State, varargin{:});elsegui_mainfcn(gui_State, varargin{:});end% End initialization code - DO NOT EDIT% --- Executes just before PCM is made visible.function PCM_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 PCM (see VARARGIN)% Choose default command line output for PCMhandles.output = hObject;% Update handles structureguidata(hObject, handles);% UIWAIT makes PCM wait for user response (see UIRESUME)% uiwait(handles.figure1);% --- Outputs from this function are returned to the command line.function varargout = PCM_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 structurevarargout{1} = handles.output;% --- 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% handles structure with handles and user data (see GUIDATA)if (get(handles.radiobutton2,'Value') == get(handles.radiobutton2,'Max')) % Verifies if Sine wave was selectedt=linspace(0,1,60); % Creates the time variable from 0 to 1 with a length of 60 or 60 pointsy=sin(2*pi*t); % Creates a sine wave of frequency 1 with the t vector axes(handles.axesanalog) % Select the proper axes plot(t,y); xlabel('Time');ylabel('Amplitude');grid on;elseif (get(handles.radiobutton3,'Value') == get(handles.radiobutton3,'Max')) % Verifies if Random signal was selectedt=linspace(0,60,60); % Creates the time variable from 0 to 60 with a length of 60 or 60 pointsy=rand([1 60]); % Creates a random signal of length 60 or with 60 pointsaxes(handles.axesanalog) % Select the proper axes plot(t,y);xlabel('Time');ylabel('Amplitude');grid on;endhandles.amp=y; % Saves the input signal y in the amp variable at the handles structurehandles.time=t; % Saves the input signal t in the time variable at the handles structureguidata(gcbo,handles); % Save the changes made to the handles structure% --- Executes on button press in pushbutton3.function pushbutton3_Callback(hObject, eventdata, handles)% hObject handle to pushbutton3 (see GCBO)% eventdata reserved - to be defined in a future version of MATLAB% handles structure with handles and user data (see GUIDATA)close; % Close the application% --- Executes on button press in pushbutton4.function pushbutton4_Callback(hObject, eventdata, handles)% hObject handle to pushbutton4 (see GCBO)% eventdata reserved - to be defined in a future version of MATLAB% handles structure with handles and user data (see GUIDATA)if (get(handles.radiobutton4,'Value') == get(handles.radiobutton4,'Max'))t=handles.time; % recover the saved variable t from the handles structurey=handles.amp; % recover the saved variable y from the handles structurep=ones(1, length(t)); % creates a vector containing only ones outideal=p.*y; % Multiplies the two vectors to get the output of an ideal sampleraxes(handles.axessampled) % Select the proper axesstem(t,outideal,'ro');xlabel('Time');ylabel('Amplitude');grid on;handles.signal=outideal;guidata(gcbo,handles);elseif (get(handles.radiobutton5,'Value') == get(handles.radiobutton5,'Max'))t=handles.time; % recover the saved variable t from the handles structurey=handles.amp; % recover the saved variable y from the handles structurep=ones(1, length(t)); % creates a vector containing only ones outhold=p.*y; % Multiplies the two vectors to get the output of an ideal sampleraxes(handles.axessampled) % Select the proper axesstairs(t,outhold,'r'); %Plot the signal in a stairs shape making it looks like a zero order hold samplerxlabel('Time');ylabel('Amplitude');grid on;handles.signal=outhold;guidata(gcbo,handles);elseif (get(handles.radiobutton6,'Value') == get(handles.radiobutton6,'Max'))t=handles.time; % recover the saved variable t from the handles structurey=handles.amp; % recover the saved variable y from the handles structuretest1=eval(get(handles.edit1,'String')); % Evals the value that is contained in the Edit 1if isnan(test1) % Test if it is a number or not. If not it displays an error messageerrordlg('You must enter a numeric value','Bad Input','modal')endlenp=length(t)/length(test1); %Calculates the length of the vector so it can make it a periodic signal with the %right size so it can work properlyp=ones(1, lenp); % Creates a vector of only ones of lenght lenp per=test1'*p; % Creates a matrix, containing lenp times the vector test1per=per(:); % Concatenates the columns of the matrix so it becomes a vectoroutnormal=per'.*y; % Multiplies the two vectors to get the output of a normal sampleraxes(handles.axessampled) % Select the proper axesplot(t,outnormal,'r');xlabel('Time');ylabel('Amplitude');grid on;handles.signal=outnormal;guidata(gcbo,handles);endfunction edit1_Callback(hObject, eventdata, handles)% hObject handle to edit1 (see GCBO)% eventdata reserved - to be defined in a future version of MATLAB% handles structure with handles and user data (see GUIDATA)% Hints: get(hObject,'String') returns contents of edit1 as text% str2double(get(hObject,'String')) returns contents of edit1 as a double% --- Executes during object creation, after setting all properties.function edit1_CreateFcn(hObject, eventdata, handles)% hObject handle to edit1 (see GCBO)% eventdata reserved - to be defined in a future version of MATLAB% handles empty - handles not created until after all CreateFcns called% Hint: edit 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

四、运行结果

五、matlab版本及参考文献

1 matlab版本

a

2 参考文献

[1] 沈再阳.精通MATLAB信号处理[M].清华大学出版社，.

[2]高宝建,彭进业,王琳,潘建寿.信号与系统——使用MATLAB分析与实现[M].清华大学出版社，.

[3]王文光,魏少明,任欣.信号处理与系统分析的MATLAB实现[M].电子工业出版社，.

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