今天繼續(xù)定點(diǎn)的工作，定點(diǎn)上使用PR控制還是有很意義的，畢竟浮點(diǎn)單片機(jī)很貴。

以前在浮點(diǎn)的開發(fā)可見：準(zhǔn)比例諧振控制器(QPR)的離散化與代碼實(shí)現(xiàn)

定點(diǎn)實(shí)現(xiàn)：考慮到量化誤差，直接把PR的IIR2函數(shù)運(yùn)行在IQ26上，這樣比單精度浮點(diǎn)精度提升4倍，整數(shù)還有最大32的數(shù)字，這樣足夠滿足PR控制的輸出動態(tài)范圍，實(shí)在不行還可以把PR的輸出在直接擴(kuò)大2^N倍來滿足控制器的調(diào)制范圍。

IIR2定義：

typedef struct IIR_2ORDER_IQ_TAG{

    Uint16 coeff_init_flag;

    _iq filter_out;

    _iq filter_W0;

    _iq filter_W1;

    _iq filter_W2;

    _iq coeff_B0;

    _iq coeff_B1;

    _iq coeff_B2;

    _iq coeff_A1;

    _iq coeff_A2;

}IIR_2ORD_IQ_DATA_DEF;

函數(shù)：

static inline _iq iir2_IQ_func_(volatile _iq input, volatile IIR_2ORD_IQ_DATA_DEF *p)

{

    //

    // w0 = x(0) - A1 * W1 - A2 * W2

    //

   p->filter_W0 = input - _IQ26mpy(p->coeff_A1, p->filter_W1) - _IQ26mpy(p->coeff_A2, p->filter_W2);

   //

   // Y(0) = Gain * (B0 * W0 + B1 * W1 + B2 * W2)

   //

   p->filter_out = _IQ26mpy(p->coeff_B0, p->filter_W0) + _IQ26mpy(p->coeff_B1, p->filter_W1) + _IQ26mpy(p->coeff_B2, p->filter_W2);

   //

   // Update last data

   //

   p->filter_W2 = p->filter_W1;

   p->filter_W1 = p->filter_W0;

    return(p->filter_out);

}

PR控制系數(shù)計(jì)算，輸入直接使用浮點(diǎn)數(shù)字，這樣調(diào)試參數(shù)畢竟安逸，IQ26的系數(shù)計(jì)算在該函數(shù)里面進(jìn)行：

static inline void updata_pr_ctrl_coeff_IQ( volatile IIR_2ORD_IQ_DATA_DEF *p,

                                            float32 kr,

                                            float32 wc,

                                            float32 wr,

                                            float32 kp,

                                            float32 ts)

{

    // with KP gain

    float32 ts_x_ts = ts * ts;

    float32 wr_x_wr = wr * wr;

    float32 div_x = ts * ts * wr * wr + 4.0f * wc * ts + 4.0f;

#if 1

    p->coeff_B0 = _IQ26((4.0f * kp + kp * ts_x_ts * wr_x_wr + 4.0f * kp * ts * wc + 4.0f * kr * wc * ts)/div_x);

    p->coeff_B1 = _IQ26(-1.0f * (8.0f * kp - 2.0f * kp * ts_x_ts * wr_x_wr)/div_x);

    p->coeff_B2 = _IQ26((4.0f * kp + kp * ts_x_ts * wr_x_wr - 4.0f * kp * ts * wc - 4.0f * kr * ts * wc)/div_x);

    p->coeff_A1 = _IQ26((2.0f * ts_x_ts * wr_x_wr - 8.0f)/div_x);

    p->coeff_A2 = _IQ26((ts_x_ts * wr_x_wr - 4.0f * ts * wc + 4.0f)/div_x);

#else

    // without KP gain

    float32 coeff_B0 = (4.0f * kr * wc * ts)/div_x;

    float32 coeff_B1 = 0;

    float32 coeff_B2 = -1.0f * p->coeff_B0;

    float32 coeff_A1 = (2.0f * ts_x_ts * wr_x_wr - 8.0f)/div_x;

    float32 coeff_A2 = (ts_x_ts * wr_x_wr - 4.0f * ts * wc + 4.0f)/div_x;

    p->coeff_B0 = _IQ(coeff_B0);

    p->coeff_B1 = _IQ(coeff_B1);

    p->coeff_B2 = _IQ(coeff_B2);

    p->coeff_A1 = _IQ(coeff_A1);

    p->coeff_A2 = _IQ(coeff_A2);

#endif

}

PR數(shù)據(jù)結(jié)構(gòu)定義

typedef struct PR_CTRL_LAW_DATA_IQ_TAG{

    IIR_2ORD_IQ_DATA_DEF f_1st;

    IIR_2ORD_IQ_DATA_DEF f_3st;

    IIR_2ORD_IQ_DATA_DEF f_5st;

    IIR_2ORD_IQ_DATA_DEF lead_lag_comp;

    _iq f1stOut;

    _iq f3rdOut;

    _iq f5thOut;

    _iq max;

    _iq min;

    _iq pr_ctrl_out;

}PR_CTRL_IQ_DATA_DEF;

PR+超前滯后補(bǔ)償：

static inline _iq pr_ctrl_IQ_func( _iq error, PR_CTRL_IQ_DATA_DEF *p)

{

    const _iq error_iq26 = _IQmpy4(error);

    p->f1stOut = iir2_IQ_func_(error_iq26, &p->f_1st);

    p->f3rdOut = iir2_IQ_func_(error_iq26, &p->f_3st);

    p->f5thOut = iir2_IQ_func_(error_iq26, &p->f_5st);

    p->pr_ctrl_out = (p->f1stOut + p->f3rdOut + p->f5thOut);

    p->pr_ctrl_out = iir2_IQ_func_(p->pr_ctrl_out, &p->lead_lag_comp);

    _IQsat(p->pr_ctrl_out, p->max, p->min);

    return(_IQdiv4(p->pr_ctrl_out));

}

PR控制函數(shù)整體參數(shù)計(jì)算：

static  void pr_ctrl_coeff_IQ_func(

                                         PR_CTRL_IQ_DATA_DEF *p,

                                        float32 grid_freq,

                                        float32 kp,

                                        float32 kr,

                                        float32 ts,

                                        float32 lead_fz,

                                        float32 lead_fp,

                                        float32 max,

                                        float32 min)

{

    updata_pr_ctrl_coeff_IQ(&p->f_1st, kr, 2.0f * M_PI, 2.0f * M_PI * grid_freq, kp, ts);

    updata_pr_ctrl_coeff_IQ(&p->f_3st, kr, 2.0f * M_PI, 2.0f * M_PI * grid_freq * 3.0f, kp, ts);

    updata_pr_ctrl_coeff_IQ(&p->f_5st, kr, 2.0f * M_PI, 2.0f * M_PI * grid_freq * 5.0f, kp, ts);

    float32 ts_x_wz = ts * 2.0f * M_PI * lead_fz;

    float32 ts_x_wp_puls_2 = ts * 2.0f * M_PI * lead_fp + 2.0f;

    p->lead_lag_comp.coeff_B0 = _IQ((ts_x_wz + 2.0f)/ts_x_wp_puls_2);

    p->lead_lag_comp.coeff_B1 = _IQ((ts_x_wz - 2.0f)/ts_x_wp_puls_2);

    p->lead_lag_comp.coeff_B2 = 0;

    p->lead_lag_comp.coeff_A1 = _IQ((ts * 2.0f * M_PI * lead_fp - 2.0f)/ts_x_wp_puls_2);

    p->lead_lag_comp.coeff_A2 = 0;

    p->max = _IQ(max);

    p->min = _IQ(min);

    p->pr_ctrl_out = 0;

}

運(yùn)行測試：

對比maltab：

PR函數(shù)離散化系數(shù)對比，上為matlab自帶函數(shù)轉(zhuǎn)換，下為上文編寫的系數(shù)轉(zhuǎn)換，對比DSP運(yùn)行的結(jié)果，適應(yīng)IQ26轉(zhuǎn)換后，系數(shù)具有較高的精度。

適應(yīng)PR控制135次再組合超前補(bǔ)償器來補(bǔ)償PR的相位突變引起的不穩(wěn)定情況。

本人能力有限，正在學(xué)習(xí)定點(diǎn)編程，如有錯誤懇請幫忙指正，謝謝。