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#include #include //MCU: stc8f2k08s2 //兰峰控制xc1004四轴SPI运动控制芯片 sfr P0M1 = 0x93; sfr P0M0 = 0x94; sfr P1M1 = 0x91; sfr P1M0 = 0x92; sfr P2M1 = 0x95; sfr P2M0 = 0x96; sfr P3M1 = 0xb1; sfr P3M0 = 0xb2; sfr P4M1 = 0xb3; sfr P4M0 = 0xb4; sfr P5M1 = 0xC9; sfr P5M0 = 0xCA; sfr P6M1 = 0xCB; sfr P6M0 = 0xCC; sfr P7M1 = 0xE1; sfr P7M0 = 0xE2; sfr P5 = 0xC8; sfr SPSTAT = 0xcd; sfr SPCTL = 0xce; sfr SPDAT = 0xcf; sfr IE2 = 0xaf; sfr AUXR = 0x8e; sfr T2H = 0xd6; sfr T2L = 0xd7; sfr P_SW2 = 0xba; #define CKSEL (*(unsigned char volatile xdata *)0xfe00) #define CKDIV (*(unsigned char volatile xdata *)0xfe01) #define IRC24MCR (*(unsigned char volatile xdata *)0xfe02) #define XOSCCR (*(unsigned char volatile xdata *)0xfe03) #define IRC32KCR (*(unsigned char volatile xdata *)0xfe04) //#define FOSC 16000000UL //使用外部16M晶振 #define FOSC 24000000UL //使用内部24M晶振 #define BRT (65536 - FOSC / 115200 / 4) //定义115200波特率 sbit b2 = P1^1; sbit b1 = P5^5; sbit led = P3^5; sbit cs3 = P3^3; sbit cs2 = P3^2; sbit cs1 = P1^2; sbit sck = P1^5; sbit in = P1^4; sbit out = P1^3; #define SPI3_CSHIGH cs3=1 // CS3 #define SPI3_CSLOW cs3=0 #define SPI2_CSHIGH cs2=1 // CS2 #define SPI2_CSLOW cs2=0 #define SPI1_CSHIGH cs1=1 // CS1 #define SPI1_CSLOW cs1=0 #define SPI_SCKHIGH sck=1 //SCK #define SPI_SCKLOW sck=0 #define SPI_OUTHIGH out=1 #define SPI_OUTLOW out=0//MOSI #define SPI_IN in//MISO unsigned char inbuf[50] = {0}; unsigned char b1_state=0; long sxnum; void initial() { P1M1 = 0; P1M0 = 0x2c; // 引脚模拟通信时,MOSI,SCK, CS 设为推挽输出 SPI1_CSHIGH; //CS不使用时设为高 SPI2_CSHIGH; SPI3_CSHIGH; SPI_SCKLOW;//SCK空闲状态一定要为低电平。 /////// spi模拟通信时不用 SPCTL = 0xd0; //使能SPI主机模式 SPSTAT = 0xc0; //清中断标志 CKDIV=1; } void init_uart() { SCON = 0x50; T2L = BRT; T2H = BRT >> 8; AUXR = 0x15; } /* 串口发送一个字节。 */ void USART_Txbyte(unsigned char i) { SBUF = i; while(TI ==0); TI = 0; } /* 串口发送一串数据。 */ void USRAT_transmit(unsigned char *fdata,unsigned char len) { unsigned char i; for(i=0;i>24; OutByte[4] = acc >>16; OutByte[5] = acc >>8; OutByte[6] = acc ; OutByte[7] = speed >>24; OutByte[8] = speed >>16; OutByte[9] = speed >>8; OutByte[10] = speed ; OutByte[11] = dec >>24; OutByte[12] = dec >>16; OutByte[13] = dec >>8; OutByte[14] = dec ; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); SPI_SendData(OutByte[3]); SPI_SendData(OutByte[4]); SPI_SendData(OutByte[5]); SPI_SendData(OutByte[6]); SPI_SendData(OutByte[7]); SPI_SendData(OutByte[8]); SPI_SendData(OutByte[9]); SPI_SendData(OutByte[10]); SPI_SendData(OutByte[11]); SPI_SendData(OutByte[12]); SPI_SendData(OutByte[13]); SPI_SendData(OutByte[14]); disabled_cs(cardno); delay_nms(1); } /* 函数名: change_speed 功能: 改变当前正在运行的轴的速度 参数: cardno 卡号 axis 轴号(1,2,3,4) speed 运行频率为:值(Hz) */ void change_speed(unsigned char cardno ,unsigned char axis, long speed ) { unsigned char OutByte[25]; OutByte[0] = 0x11 ; OutByte[1] = 0 ; OutByte[2] = axis ; OutByte[3] = speed >>24; OutByte[4] = speed >>16; OutByte[5] = speed >>8; OutByte[6] = speed ; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); SPI_SendData(OutByte[3]); SPI_SendData(OutByte[4]); SPI_SendData(OutByte[5]); SPI_SendData(OutByte[6]); disabled_cs(cardno); delay_nms(1); } /* 函数名: set_command_pos 功能: 设置轴逻辑位置 参数: cardno 卡号 axis 轴号(1,2,3,4) pulse 位置脉冲数,范围(-268435455~+268435455) */ void set_command_pos(unsigned char cardno ,unsigned char axis, long value ) { unsigned char OutByte[25]; OutByte[0] = 0x12 ; OutByte[1] = 0 ; OutByte[2] = axis ; OutByte[3] = value >>24; OutByte[4] = value >>16; OutByte[5] = value >>8; OutByte[6] = value ; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); SPI_SendData(OutByte[3]); SPI_SendData(OutByte[4]); SPI_SendData(OutByte[5]); SPI_SendData(OutByte[6]); disabled_cs(cardno); delay_nms(1); } /* 函数名: sudden_stop 功能: 轴立即停止 参数: cardno 卡号 axis 停止的轴号(1,2,3,4) mode 0:急停并清空后面缓存的指令 2:急停不清后面缓存的指令 */ void sudden_stop(unsigned char cardno ,unsigned char axis ,unsigned char mode) { unsigned char OutByte[25]; OutByte[0] = 0x17 ; OutByte[1] = axis ; OutByte[2] = mode; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); disabled_cs(cardno); delay_nms(1); } /* 函数名: set_special 功能:设置特别功能 参数: cardno 卡号 value 0xfc 缓存插补运动暂停 0xfd 取消缓存插补暂停 */ void set_special(unsigned char cardno,unsigned char value) { unsigned char OutByte[25]; OutByte[0] = 0xFA ; OutByte[1] = 0; OutByte[2] = value; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); disabled_cs(cardno); delay_nms(1); } /* 函数名: get_inp_state 功能: 获取轴状态,缓存剩余量,各轴逻辑位置。 参数: cardno 卡号 amount 获取字节数量。 设为22将取全部数据。 inbuf[] 读取的数据存放的数组 */ void get_inp_state( unsigned char cardno, unsigned char amount,unsigned char tinbuf[50]) { unsigned char OutByte[50]; char i; enabled_cs(cardno); tinbuf[0]=SPI_SendData(0x04); for(i=1;i>24; OutByte[4] = speed1 >>16; OutByte[5] = speed1>> 8; OutByte[6] = speed1; OutByte[7] = speed2 >>24; OutByte[8] = speed2 >>16; OutByte[9] = speed2 >>8; OutByte[10] = speed2 ; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); SPI_SendData(OutByte[3]); SPI_SendData(OutByte[4]); SPI_SendData(OutByte[5]); SPI_SendData(OutByte[6]); SPI_SendData(OutByte[7]); SPI_SendData(OutByte[8]); SPI_SendData(OutByte[9]); SPI_SendData(OutByte[10]); disabled_cs(cardno); delay_nms(1); } /* 函数名: inp_move4 功能:四轴直线插补 参数: cardno 卡号 no1 X轴轴号 no2 Y轴轴号 no3 Z轴轴号 no4 E轴轴号 pulse1,pulse2,pulse3,pulse4 X-Y-Z-E轴移动的距离,范围(-8388608~+8388607) mode 0:绝对位移 1:相对位移 */ void inp_move4(unsigned char cardno,unsigned char no1 ,unsigned char no2 ,unsigned char no3 ,unsigned char no4, long pulse1 ,long pulse2 ,long pulse3 ,long pulse4 ,unsigned char mode ) { unsigned char OutByte[25]; OutByte[0] = 0xa; OutByte[1] = no1; OutByte[2] = no2; OutByte[3] = no3; OutByte[4] = no4; OutByte[5] = pulse1>>24; OutByte[6] = pulse1 >>16; OutByte[7] = pulse1>> 8; OutByte[8] = pulse1; OutByte[9] = pulse2 >>24; OutByte[10] = pulse2 >>16; OutByte[11] = pulse2 >>8; OutByte[12] = pulse2 ; OutByte[13] = pulse3 >>24; OutByte[14] = pulse3 >>16; OutByte[15] = pulse3 >>8; OutByte[16] = pulse3 ; OutByte[17] = pulse4 >>24; OutByte[18] = pulse4 >>16; OutByte[19] = pulse4 >>8; OutByte[20] = pulse4 ; OutByte[21] = 0 ; OutByte[22] = mode; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); SPI_SendData(OutByte[3]); SPI_SendData(OutByte[4]); SPI_SendData(OutByte[5]); SPI_SendData(OutByte[6]); SPI_SendData(OutByte[7]); SPI_SendData(OutByte[8]); SPI_SendData(OutByte[9]); SPI_SendData(OutByte[10]); SPI_SendData(OutByte[11]); SPI_SendData(OutByte[12]); SPI_SendData(OutByte[13]); SPI_SendData(OutByte[14]); SPI_SendData(OutByte[15]); SPI_SendData(OutByte[16]); SPI_SendData(OutByte[17]); SPI_SendData(OutByte[18]); SPI_SendData(OutByte[19]); SPI_SendData(OutByte[20]); SPI_SendData(OutByte[21]); SPI_SendData(OutByte[22]); disabled_cs(cardno); delay_nms(100); } /* 函数名: inp_arc 功能:二轴圆弧插补 参数: cardno 卡号 no1 参与插补X轴的轴号 no2 参与插补Y轴的轴号 x,y 圆弧插补的终点位置(相对于起点),范围(-8388608~+8388607) i,j 圆弧插补的圆心点位置(相对于起点),范围(-8388608~+8388607) mode1 0:圆心法逆时针插补 1:圆心法顺时针插补 2:三点圆弧 3:半径法逆时针插补 4:半径法顺时针插补 mode2 0:绝对位移 1:相对位移 */ void inp_arc(unsigned char cardno ,unsigned char no1,unsigned char no2, long x , long y, long i, long j,unsigned char mode1,unsigned char mode2 ) { unsigned char OutByte[25]; OutByte[0] = 0xc; OutByte[1] = no1; OutByte[2] = no2; OutByte[3] = x >>24; OutByte[4] = x >>16; OutByte[5] = x >>8; OutByte[6] = x ; OutByte[7] = y >>24; OutByte[8] = y >>16; OutByte[9] = y >>8; OutByte[10] = y ; OutByte[11] = i >>24; OutByte[12] = i >>16; OutByte[13] = i >>8; OutByte[14] = i ; OutByte[15] = j >>24; OutByte[16] = j >>16; OutByte[17] = j >>8; OutByte[18] = j ; OutByte[19] = mode1; OutByte[20] = mode2; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); SPI_SendData(OutByte[3]); SPI_SendData(OutByte[4]); SPI_SendData(OutByte[5]); SPI_SendData(OutByte[6]); SPI_SendData(OutByte[7]); SPI_SendData(OutByte[8]); SPI_SendData(OutByte[9]); SPI_SendData(OutByte[10]); SPI_SendData(OutByte[11]); SPI_SendData(OutByte[12]); SPI_SendData(OutByte[13]); SPI_SendData(OutByte[14]); SPI_SendData(OutByte[15]); SPI_SendData(OutByte[16]); SPI_SendData(OutByte[17]); SPI_SendData(OutByte[18]); SPI_SendData(OutByte[19]); SPI_SendData(OutByte[20]); disabled_cs(cardno); delay_nms(100); } /* 函数名: inp_helical 功能:圆弧螺旋插补 参数: cardno 卡号 no1 参与插补X轴的轴号 no2 参与插补Y轴的轴号 no3 参与插补螺旋轴的轴号 x,y 圆弧插补的终点位置(相对于起点),范围(-8388608~+8388607) z 参与插补螺旋轴的位置(相对于起点) i,j 圆弧插补的圆心点位置(相对于起点),范围(-8388608~+8388607) mode1 0:逆时针插补 1:顺时针插补 mode2 0:绝对位移 1:相对位移 */ /* void inp_helical(unsigned char cardno ,unsigned char no1,unsigned char no2,unsigned char no3,long x , long y,long z, long i, long j,unsigned char mode1,unsigned char mode2 ) { unsigned char OutByte[30]; OutByte[0] = 0xd; OutByte[1] = no1; OutByte[2] = no2; OutByte[3] = no3; OutByte[4] = x >>24; OutByte[5] = x >>16; OutByte[6] = x >>8; OutByte[7] = x ; OutByte[8] = y >>24; OutByte[9] = y >>16; OutByte[10] = y >>8; OutByte[11] = y ; OutByte[12] = z >>24; OutByte[13] = z >>16; OutByte[14] = z >>8; OutByte[15] = z ; OutByte[16] = i >>24; OutByte[17] = i >>16; OutByte[18] = i >>8; OutByte[19] = i ; OutByte[20] = j >>24; OutByte[21] = j >>16; OutByte[22] = j >>8; OutByte[23] = j ; OutByte[24] = mode1; OutByte[25] = mode2; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); SPI_SendData(OutByte[3]); SPI_SendData(OutByte[4]); SPI_SendData(OutByte[5]); SPI_SendData(OutByte[6]); SPI_SendData(OutByte[7]); SPI_SendData(OutByte[8]); SPI_SendData(OutByte[9]); SPI_SendData(OutByte[10]); SPI_SendData(OutByte[11]); SPI_SendData(OutByte[12]); SPI_SendData(OutByte[13]); SPI_SendData(OutByte[14]); SPI_SendData(OutByte[15]); SPI_SendData(OutByte[16]); SPI_SendData(OutByte[17]); SPI_SendData(OutByte[18]); SPI_SendData(OutByte[19]); SPI_SendData(OutByte[20]); SPI_SendData(OutByte[21]); SPI_SendData(OutByte[22]); SPI_SendData(OutByte[23]); SPI_SendData(OutByte[24]); SPI_SendData(OutByte[25]); disabled_cs(cardno); delay_nms(1); } */ /* 函数名: write_bit 功能:写输出口状态 参数: cardno 卡号 number 端口号(0-6) Y0-Y6 value 状态(0,1) 0 输出低电平 1 输出高电平 */ void write_bit(unsigned char cardno , unsigned char number, unsigned char value) { unsigned char OutByte[25]; OutByte[0] = 0x03 ; OutByte[1] = number; OutByte[2] = value; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); disabled_cs(cardno); delay_nms(1); } /* 函数名: wait_delay 功能:等待延时数 参数: cardno 卡号 value 延时量(1-10000)MS */ void wait_delay(unsigned char cardno ,unsigned int value) { unsigned char OutByte[25]; OutByte[0] = 0x0e ; OutByte[1] = value>>8; OutByte[2] = value; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); disabled_cs(cardno); delay_nms(1); } /* 函数名: pmove 功能: e版本单轴运行 参数: cardno 卡号 axis 轴号 mode 0:绝对位移 1:相对位移 pulse1 轴移动的距离,范围(-8388608~+8388607) */ void pmove(unsigned char cardno,unsigned char axis,unsigned char mode, long pulse1 ) { unsigned char OutByte[25]; OutByte[0] = 0x2; OutByte[1] = axis ; OutByte[2] = mode; OutByte[3] = pulse1>>24; OutByte[4] = pulse1 >>16; OutByte[5] = pulse1>>8; OutByte[6] = pulse1; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); SPI_SendData(OutByte[3]); SPI_SendData(OutByte[4]); SPI_SendData(OutByte[5]); SPI_SendData(OutByte[6]); disabled_cs(cardno); delay_nms(1); } /* 函数名: wait_stop 功能: e版本等待轴停止 参数: cardno 卡号 axis 停止的轴号(1,2,3,4) mode 0:急停并清空后面缓存的指令 2:急停不清后面缓存的指令 */ void wait_stop(unsigned char cardno ,unsigned char axis) { unsigned char OutByte[25]; OutByte[0] = 0xf ; OutByte[1] = axis ; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); disabled_cs(cardno); delay_nms(1); } /* 函数名: set_cam 功能: 设置电子凸轮 参数: cardno 卡号 num 凸轮表数据段行号 xa 主轴编码器脉冲数 xb 从轴脉冲数 style 从轴运动方式 */ void set_cam(unsigned char cardno ,unsigned int num ,unsigned long xa ,unsigned long xb,unsigned char style ) { unsigned char OutByte[25]; OutByte[0] = 0x21; OutByte[1] = num >>8; OutByte[2] = num; OutByte[3] = xa >>24; OutByte[4] = xa >>16; OutByte[5] = xa >>8; OutByte[6] = xa ; OutByte[7] = xb >>24; OutByte[8] = xb >>16; OutByte[9] = xb >>8; OutByte[10] = xb ; OutByte[11] = style ; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); SPI_SendData(OutByte[3]); SPI_SendData(OutByte[4]); SPI_SendData(OutByte[5]); SPI_SendData(OutByte[6]); SPI_SendData(OutByte[7]); SPI_SendData(OutByte[8]); SPI_SendData(OutByte[9]); SPI_SendData(OutByte[10]); SPI_SendData(OutByte[11]); disabled_cs(cardno); delay_nms(1); } /* 函数名: run_cam 功能: 运行电子凸轮 参数: cardno 卡号 axis 从轴轴号 mode 从轴运动方式 snum 数据段起始行号 dnum 数据段结束行号 */ void run_cam(unsigned char cardno,unsigned char axis,unsigned char mode ,unsigned int snum ,unsigned int dnum ) { unsigned char OutByte[25]; OutByte[0] = 0x22; OutByte[1] = axis; OutByte[2] = mode; OutByte[3] = snum >>8; OutByte[4] = snum ; OutByte[5] = dnum >>8; OutByte[6] = dnum ; enabled_cs(cardno); SPI_SendData(OutByte[0]); SPI_SendData(OutByte[1]); SPI_SendData(OutByte[2]); SPI_SendData(OutByte[3]); SPI_SendData(OutByte[4]); SPI_SendData(OutByte[5]); SPI_SendData(OutByte[6]); disabled_cs(cardno); delay_nms(1); } void main(void) { initial(); init_uart(); // ES = 1; // EA = 1; // P_SW2 = 0x80; // XOSCCR = 0xc0; //启动外部晶振 // while (!(XOSCCR & 1)); //等待时钟稳定 // CKDIV = 0x00; //时钟不分频 // CKSEL = 0x01; //选择外部晶振 // P_SW2 = 0x00; led=0; delay_nms(100) ; /*下面指令为e型无缓存1轴2轴手动方式回原点,xc1006适用 set_speed(1 ,1,80000,10000,80000); // 设1轴速度 set_speed(1 ,2,80000,10000,80000); // 设2轴速度 pmove(1,1,1, -320000000); // 1轴多脉冲负方向运动 ,原点开关有效会停下 pmove(1,2,1, -320000000); // 2轴多脉冲负方向运动,原点开关有效会停下 do { get_inp_state( 1, 4,inbuf); //只需读出4个字节来判断轴状态 } while(inbuf[1]); //通过返回的第二个字节里面的4个位获取各轴状态,不全为0时表示轴还没停止 ,一直等到全为0 set_command_pos(1,1,0); // 设1轴此时坐标为0 set_command_pos(1,2,0); // 设2轴此时坐标为0 */ /*下面的指令为f型1,2轴使用回原点指令自动二次回原点 go_home(1,1,30000,5000 ) ; // 1轴回原点 go_home(1,2,30000,5000 ) ; // 2轴回原点 do { get_inp_state( 1, 4,inbuf); //只需读出4个字节来判断轴状态 } while(inbuf[3]); // 等待缓存数量为0 ,如果多条运动指令在缓存里 ,可以读取缓存数量来判断指令有没执行完成。 //while(inbuf[1]); // 等待轴停止 ,如果只有一条除圆弧外的运动指令,可以读取轴状态来判断有没执行完。 set_command_pos(1 ,1,0); //设1轴坐标 set_command_pos(1 ,2,0); //设2轴坐标 */ //set_speed(1 ,1,80000,20000,80000); //设置1轴运行速度20K,加速度80k //set_speed(1 ,2,80000,20000,80000); // 设置2轴运行速度20K,加速度80k //set_speed(1 ,3,80000,20000,80000); // 设置3轴运行速度20K,加速度80k //set_speed(1 ,4,80000,20000,80000); //设置4轴运行速度20K,加速度80k // sudden_stop(1,1,3); // set_speed(1 ,1,1600,1600,1600); // set_command_pos(1,1, 0x00f8 ) ; // set_special(1,0xea); //pmove(1,1,1, 3200); while(1) { // write_bit(1 , 1, 0) ; // pmove(1,1,1, 3200); if(!b1) //按下按键 { delay_nms(10); if(!b1) { //go_home(1,1,30000,5000 ) ; // 1轴回原点 set_speed(1 ,1,80000,20000,80000); // pmove(1,1,1, 32000); // USART_Txbyte(0x38); /*下面指令为e型无缓存运行 ,xc1006适用 pmove(1,1,1, 3200); // 1轴正方向运动 pmove(1,2,1, 6400); // 2轴正方向运动 do { get_inp_state( 1, 4,inbuf); //只需读出4个字节来判断轴状态 } while(inbuf[1]&(1<<0)); //通过返回的第二个字节里面的0位获取1轴状态,直到1轴停止 pmove(1,1,1, -3200); // 1轴负方向运动 */ //set_speed(1 ,1,80000,20000,80000); //设置1轴运行速度20K,加速度80k //set_speed(1 ,2,80000,20000,80000); // 设置2轴运行速度20K,加速度80k //set_speed(1 ,3,80000,20000,80000); // 设置3轴运行速度20K,加速度80k // set_speed(1 ,4,80000,20000,80000); //设置4轴运行速度20K,加速度80k // pmove(1,1,1, 2); // pmove(1,1,0, 0); // pmove(1,1,1, 20000); // pmove(1,3,1, 2); // pmove(1,4,1, 2); inp_move4(1,3,2,1,0,20000 ,20000,20000 ,0 ,1); // 4轴直线插补 // inp_move4(1,1,2,0,0,20000 ,20000,0 ,0 ,1); // 4轴直线插补 /*e型带缓存测试指令*/ // set_speed(1 ,1,200000,50000,80000); //设置1轴运行速度50K,加速度200k // set_speed(1 ,2,200000,50000,80000); //设置1轴运行速度50K,加速度200k // set_speed(1 ,3,40000,10000,80000); //设置1轴运行速度10K,加速度40k //write_bit(1 , 6, 0); // Y6输出低 // pmove(1,1,1, 1000); //1轴相对运行速1000个脉冲 // pmove(1,2,1, 1000); // 2轴相对运行速1000个脉冲 //wait_stop(1 ,1); //等待1轴停止 //wait_stop(1 ,2); //等待2轴停止 // wait_delay(1 ,500); // 延时500MS // pmove(1,3,1, 1000); //3轴相对运行速1000个脉冲 //write_bit(1 , 6, 1); // Y6输出高 /*f型测试指令*/ // write_bit(1 , 6, 0); // set_speed(1 ,1,200000,50000,80000); //设置运行速度50K,加速度200h // wait_delay(1 ,500); // 延时500MS // write_bit(1 , 2, 0); // inp_move4(1,1,0,0,0,80000 ,0,0 ,0 ,1); // 1,2轴插补 // set_speed(1,1 ,800000,25000,80000); //设置运行速度25K,加速度800K //inp_move4(1,1,2,0,0,20000 ,10000,0 ,0 ,1); // 1,2轴插补 // inp_arc(1 ,1,2, -20000, 20000, -20000, 0,0,1) ; // 1,2轴圆弧插补 // inp_arc(1 ,1,2, -20000, 20000, -20000, 0,0,1) ; // 1,2轴圆弧插补 // inp_arc(1 ,1,2, 3200, 3200, 3200, 0,0,1) ; // 1,2轴圆弧插补 // inp_arc(1 ,1,2, 20000, 20000, 20000, 0,0,1) ; // 1,2轴圆弧插补 // inp_arc(1 ,1,2, -40000, 0, -20000, 20000,2,1) ; // 1,2轴3点圆弧插补 //set_speed(1 ,1,800000,25000,80000); //设置运行速度250K,加速度800K // inp_arc(1 ,1,2, -20000, 20000, -20000, 0,0,1) ; // wait_delay(1 ,500); // write_bit(1 , 6, 1); // wait_delay(1 ,500); // write_bit(1 , 6, 0); /*下面的指令会直接发到缓存区自动排队运行*/ // write_bit(1 , 6, 0); // Y6输出低 // set_speed(1 ,1,40000,25000,80000); // inp_move4(1,1,2,3,4,320000 ,32000,32000 ,32000 ,1); // 4轴直线插补 //wait_delay(1 ,2000); //模块内部指令间延时3S //inp_move4(1,1,2,0,0,32000 ,32000,0 ,0 ,1); // 1,2轴直线插补 // wait_delay(1 ,2000); // inp_move4(1,2,0,0,0,32000 ,0,0 ,0 ,1); // 2轴单独运行 //inp_arc(1 ,1,2, -20000, 20000, -20000, 0,0,1) ; // 2轴圆弧插补,终点相对起点坐标(-20000,20000),圆心相对起点坐标(-20000,0),逆时针方向,画出1/4圆弧。 // write_bit(1 , 6, 1); // Y6输出高 ,判断指令段有没执行完成也可以在指令段后面加一条端口输出指令,然后用单片机来读引脚来判断。 /*下面指令为D型电子凸轮追剪运行测试 */ // set_cam(1,0 ,0 ,0 ,0) ; // 初始位置 // set_cam(1,1 ,400 ,800,2 ) ; // 轴加速 //set_cam(1,2 ,800 ,2800,1 ) ; // 轴同步 //set_cam(1,3 ,1200 ,3200 ,3) ; // 轴减速 //set_cam(1,4 ,1600,400 ,2) ; // 轴反方向加速 // set_cam(1,5 ,2000,0 ,3) ; // 轴反方向减速到初始位置 //set_cam(1,6 ,3000,0 ,0) ; // 轴在初始位等待 // run_cam(1,1,1 ,0 ,6 ); // 单次运行0-6条 /*下面指令为D型电子凸轮飞剪运行测试 */ //set_cam(1,0 ,0 ,0 ,0) ; // 初始位置 //set_cam(1,1 ,400 ,3200,2 ) ; // 轴加速 //set_cam(1,2 ,800 ,9600,1 ) ; // 轴同步 //set_cam(1,3 ,1200 ,12800,3) ; // 轴减速到初始位 //set_cam(1,4 ,3000,0 ,0) ; // 轴在初始位等待 // run_cam(1,1,1 ,0 ,4 ); // 单次运行0-4条 while(!b1); } } if(!b2) //按下按键 { delay_nms(10) ; if(!b2) { // run_cam(1,1,1 ,0 ,5 ); // 凸轮表单次运行0-5条 // pmove(1,1,1, 3200); // pmove(1,2,1, 10000); USRAT_transmit(inbuf,22); // sudden_stop(1,1,0); // pmove(1,1,0, 0); // sudden_stop(1,1,0); // f型立即停止所有插补轴 ,并清缓存 。 e型立即停止1轴 ,并清缓存 。 // sudden_stop(1,2,0); // sudden_stop(1,3,0); // f型立即停止所有插补轴 ,并清缓存 。 e型立即停止1轴 ,并清缓存 。 //sudden_stop(1,4,0); //get_inp_state( 1, 28,inbuf); //读出数据放入数组 //USRAT_transmit(inbuf,28); // 串口将数组数据发送出去查看 // USART_Txbyte('\r'); // USART_Txbyte('\n'); //USART_Txbyte(0x0d); // USART_Txbyte(0x0a); while(!b2); } } // delay_nms(10) ; get_inp_state( 1, 22,inbuf); //读出数据放入数组 //USRAT_transmit(inbuf,22); // 串口将数组数据发送出去查看 //USART_Txbyte(inbuf[1]); // get_inp_state( 1, 20,inbuf); //读出数据放入数组 // USRAT_transmit(inbuf,20); // 串口将数组数据发送出去查看 // USART_Txbyte(inbuf[3]); if(inbuf[1]==0) //inbuf[1]数据为0表示所有轴都停 led=1; else led=0; // 指示LED点亮 } }
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