文章目录

前言

C MEX S-Function

算法原理

原始信号创建

编写S函数

仿真验证

Tips

分析和应用

总结

前言

见《开箱报告，Simulink Toolbox库模块使用指南（一）——powergui模块》

见《开箱报告，Simulink Toolbox库模块使用指南（二）——MATLAB Fuction模块》

见《开箱报告，Simulink Toolbox库模块使用指南（三）——Simscape 电路仿真模块》

见《开箱报告，Simulink Toolbox库模块使用指南（四）——S-Fuction模块》

C MEX S-Function

C MEX S-Function是使用C语言开发的一种S-Fuction，具备前一篇文章中讲解的S-Fuction的全部基本特性。它对应S-Fuction中的Level2类型，支持访问更广泛的 S-Function API 集，并支持代码生成。由于汽车电子工程与C语言密不可分，所以我们必须对C MEX S-Function重点关注。

Mathworks官方Help对该模块的说明如下所示。

本文以DFT算法为例，介绍如何利用C MEX S-Function搭建项目需求中高度自定义的信号解耦模块。

算法原理

傅里叶变换告诉我们，任何周期信号都可以分解为正弦波的叠加。具体的做法是：将被求解的原始信号，与目标频率的信号相乘，然后再积分，就得到了原始信号在该频率上的分量，公式如下：

原始信号：S;

目标频率信号：D_cos = cos(2pi*w*t);

目标频率信号：D_sin = sin(2pi*w*t);

目标信号实部：D_real = dot(S,D_cos)/N*2;

目标信号虚部：D_imag = dot(S,D_sin)/N*2;

目标信号模数：D_modl = sqrt(D_real^2 + D_imag^2);

原始信号创建

这里沿用前一篇文章中的电路方程模型，见《开箱报告，Simulink Toolbox库模块使用指南（四）——S-Fuction模块》

创建电压和电流信号如下：

t(S) = (0 : 4999)*0.0001;

I(A) = 4.235 + 0.035*sin(2pi * 50t + pi);

U(A) = 3.529 + 0.071*sin(2pi * 50t);

在Matlab的命令窗口中运行该动态方程，得到的电流和电压曲线，与前一篇文章一致，如下所示：

编写S函数

根据官方的Basic C MEX S-Function模板，写出的S函数完整代码如下：

#define S_FUNCTION_NAME  DFT_CMexSfunc    //函数名字，与C文件名一致
#define S_FUNCTION_LEVEL 2
#include "simstruc.h"    //Matlab宏函数库static real_T Fs = 10e3;    //信号采样频率，与信号源一致
static real_T L = 5e3;      //信号采样点个数，两者根据Nyquist定理计算/* Function: mdlInitializeSizes ===============================================* Abstract:*    The sizes information is used by Simulink to determine the S-function*    block's characteristics (number of inputs, outputs, states, etc.).*/
static void mdlInitializeSizes(SimStruct *S)
{//一个算法参数Freq，目标解算频率ssSetNumSFcnParams(S, 1);  /* Number of expected parameters */if (ssGetNumSFcnParams(S) != ssGetSFcnParamsCount(S)) {/* Return if number of expected != number of actual parameters */return;}ssSetNumContStates(S, 0);ssSetNumDiscStates(S, 4);      //离散状态的个数if (!ssSetNumInputPorts(S, 1)) return;ssSetInputPortWidth(S, 0, 1);      //一个信号输入端口，信号维度1ssSetInputPortRequiredContiguous(S, 0, true); /*direct input signal access*//** Set direct feedthrough flag (1=yes, 0=no).* A port has direct feedthrough if the input is used in either* the mdlOutputs or mdlGetTimeOfNextVarHit functions.*/ssSetInputPortDirectFeedThrough(S, 0, 1);if (!ssSetNumOutputPorts(S, 1)) return;ssSetOutputPortWidth(S, 0, 1);      //一个信号输出端口，信号维度1ssSetNumSampleTimes(S, 1);ssSetNumRWork(S, 0);ssSetNumIWork(S, 0);ssSetNumPWork(S, 0);ssSetNumModes(S, 0);ssSetNumNonsampledZCs(S, 0);/* Specify the operating point save/restore compliance to be same as a * built-in block */ssSetOperatingPointCompliance(S, USE_DEFAULT_OPERATING_POINT);ssSetOptions(S, 0);
}/* Function: mdlInitializeSampleTimes =========================================* Abstract:*    This function is used to specify the sample time(s) for your*    S-function. You must register the same number of sample times as*    specified in ssSetNumSampleTimes.*/
static void mdlInitializeSampleTimes(SimStruct *S)
{
//     ssSetSampleTime(S, 0, CONTINUOUS_SAMPLE_TIME);ssSetSampleTime(S, 0, 0.001);     //算法运行周期0.001s，不同于信号采样频率ssSetOffsetTime(S, 0, 0.0);}#define MDL_INITIALIZE_CONDITIONS   /* Change to #undef to remove function */
#if defined(MDL_INITIALIZE_CONDITIONS)/* Function: mdlInitializeConditions ========================================* Abstract:*    In this function, you should initialize the continuous and discrete*    states for your S-function block.  The initial states are placed*    in the state vector, ssGetContStates(S) or ssGetRealDiscStates(S).*    You can also perform any other initialization activities that your*    S-function may require. Note, this routine will be called at the*    start of simulation and if it is present in an enabled subsystem*    configured to reset states, it will be call when the enabled subsystem*    restarts execution to reset the states.*/static void mdlInitializeConditions(SimStruct *S){//离散状态赋初值real_T Count = 1;real_T t = 0;real_T cos_integ = 0;real_T sin_integ = 0;real_T *x0 = ssGetRealDiscStates(S);*x0++ = Count;*x0++ = t;*x0++ = cos_integ;*x0++ = sin_integ;}
#endif /* MDL_INITIALIZE_CONDITIONS */#define MDL_START  /* Change to #undef to remove function */
#if defined(MDL_START) /* Function: mdlStart =======================================================* Abstract:*    This function is called once at start of model execution. If you*    have states that should be initialized once, this is the place*    to do it.*/static void mdlStart(SimStruct *S){}
#endif /*  MDL_START *//* Function: mdlOutputs =======================================================* Abstract:*    In this function, you compute the outputs of your S-function*    block.*/
static void mdlOutputs(SimStruct *S, int_T tid)
{real_T real = 0;real_T imag = 0;real_T modl = 0;real_T *y = ssGetOutputPortSignal(S,0);real_T *x = ssGetRealDiscStates(S);if(x[0]==L+1){real = x[2]/L*2;imag = x[3]/L*2;modl = sqrt(real*real + imag*imag);y[0] = modl;       //解算结果输出}
}#define MDL_UPDATE  /* Change to #undef to remove function */
#if defined(MDL_UPDATE)/* Function: mdlUpdate ======================================================* Abstract:*    This function is called once for every major integration time step.*    Discrete states are typically updated here, but this function is useful*    for performing any tasks that should only take place once per*    integration step.*/static void mdlUpdate(SimStruct *S, int_T tid){real_T Sr_cos;real_T Sr_sin;real_T T;real_T Freq = (real_T) *mxGetPr(ssGetSFcnParam(S,0));real_T *x = ssGetRealDiscStates(S);const real_T *u = (const real_T*) ssGetInputPortSignal(S,0);if(x[0]<=L){   Sr_cos = cos(2*3.14 * Freq*x[1]);Sr_sin = sin(2*3.14 * Freq*x[1]);x[2] = x[2] + u[0]*Sr_cos;x[3] = x[3] + u[0]*Sr_sin;x[0] = x[0] + 1;T = 1/Fs;x[1] = x[1] + T;}}
#endif /* MDL_UPDATE *//* Function: mdlTerminate =====================================================* Abstract:*    In this function, you should perform any actions that are necessary*    at the termination of a simulation.  For example, if memory was*    allocated in mdlStart, this is the place to free it.*/
static void mdlTerminate(SimStruct *S)
{
}

C代码编写好之后，用Matlab指令 'mex DFT_CMexSfunc.c' 进行编译。如果代码没有错误，编译成功后会看到如下提示：

仿真验证

将上述编写好的C MEX S-Fuction模块，放入Simulink模型中进行验证，如下所示：

运行上述模型，得到的电流和电压如上图所示，也与前一篇文章一致。

至此，可以证明该C MEX S-Fuction模块可以较好地求解，耦合信号中的自信号分量。

Tips

C MEX S-Fuction模块能够让使用者充分自由地开发Simulink模块，一方面是跨语言的程序开发方式，只需要include其他c文件的头文件，即可调用其中已开发和验证好的c函数。另一方面是大量的能够与Simulink引擎交互的的宏函数，使得开发人员有了更大的发挥空间。一些常用的，必须熟练掌握宏函数如下：

1.系统输入宏函数

ssSetNumInputPorts(S, 1)

ssSetInputPortWidth(S, 0, 1)

ssSetInputPortDirectFeedThrough(S, 0, 1)

real_T *u = (real_T*) ssGetInputPortSignal(S,0);

Temp = u[0];

2.系统参数宏函数

ssSetNumSFcnParams(S, 1);

real_T Pa1 = (real_T) *mxGetPr(ssGetSFcnParam(S,0));

//real_T Pa2 = (real_T) *mxGetPr(ssGetSFcnParam(S,1));

Temp = Pa1;

3.系统周期宏函数

ssSetSampleTime(S, 0, 0.001);

ssSetOffsetTime(S, 0, 0.0);

4.系统状态宏函数

ssSetNumDiscStates(S, 4);

real_T *x = ssGetRealDiscStates(S);

*x++ = a;

*x++ = b;

*x++ = c;

*x++ = d;

x[0] = x[0] + 1;

x[1] = x[1] + 1;

x[2] = x[2] + 1;

x[3] = x[3] + 1;

5.系统输出宏函数

ssSetNumOutputPorts(S, 1)

ssSetOutputPortWidth(S, 0, 1)

real_T *y = ssGetOutputPortSignal(S,0);

y[0] = a;

//y[1] = b;

//y[2] = c;

//y[3] = d;

分析和应用

C MEX S-Fuction是S-Fuction的一种，他们的相同点一样，不同点在于灵活度和自由度进一步延伸，功能进一步扩展。比如本文举例的DFT求解模块，是在原有DFT算法的基础上进一步裁剪，只求解目标期望频率上的信号分量，并且把原本算法中集中计算的几个向量积分、乘除、开方等运算分解到每一个运算周期中，变成单个变量的运算（需要时还可以灵活调整指定N个周期把算法执行完），以此通过延长运算时间来节省算法对单个周期硬件算力的开销，不仅能够保证整个系统的实时性能，还能大大提高算法求解得数据量，以此提高求解精度。同时本文举例的DFT求解求解算法也是以前开发的，经过验证的模块功能，利用C MEX S-Fuction提供的C函数调用机制，无缝衔接的移植了过来。