基本进攻全过程

2025-06-24 15:44:28 +08:00 · 2025-06-24 15:44:28 +08:00 · 3654e052e7
commit 3654e052e7
parent ffd13d2e63
22 changed files with 487 additions and 279 deletions
--- a/Core/Inc/stm32f4xx_it.h
+++ b/Core/Inc/stm32f4xx_it.h
@ -57,7 +57,6 @@ void EXTI0_IRQHandler(void);
 void EXTI4_IRQHandler(void);
 void DMA1_Stream1_IRQHandler(void);
 void CAN1_RX0_IRQHandler(void);
 void CAN1_RX1_IRQHandler(void);
 void EXTI9_5_IRQHandler(void);
 void TIM1_UP_TIM10_IRQHandler(void);
 void USART1_IRQHandler(void);
@ -65,7 +64,6 @@ void USART3_IRQHandler(void);
 void DMA2_Stream1_IRQHandler(void);
 void DMA2_Stream2_IRQHandler(void);
 void DMA2_Stream3_IRQHandler(void);
 void CAN2_RX0_IRQHandler(void);
 void CAN2_RX1_IRQHandler(void);
 void DMA2_Stream5_IRQHandler(void);
 void DMA2_Stream6_IRQHandler(void);
--- a/Core/Src/can.c
+++ b/Core/Src/can.c
@ -81,7 +81,7 @@ void MX_CAN2_Init(void)
  hcan2.Init.AutoWakeUp = DISABLE;
  hcan2.Init.AutoRetransmission = DISABLE;
  hcan2.Init.ReceiveFifoLocked = DISABLE;
-  hcan2.Init.TransmitFifoPriority = ENABLE;
+  hcan2.Init.TransmitFifoPriority = DISABLE;
  if (HAL_CAN_Init(&hcan2) != HAL_OK)
  {
    Error_Handler();
@ -124,8 +124,6 @@ void HAL_CAN_MspInit(CAN_HandleTypeDef* canHandle)
    /* CAN1 interrupt Init */
    HAL_NVIC_SetPriority(CAN1_RX0_IRQn, 5, 0);
    HAL_NVIC_EnableIRQ(CAN1_RX0_IRQn);
    HAL_NVIC_SetPriority(CAN1_RX1_IRQn, 5, 0);
    HAL_NVIC_EnableIRQ(CAN1_RX1_IRQn);
  /* USER CODE BEGIN CAN1_MspInit 1 */
  /* USER CODE END CAN1_MspInit 1 */
@ -155,8 +153,6 @@ void HAL_CAN_MspInit(CAN_HandleTypeDef* canHandle)
    HAL_GPIO_Init(GPIOB, &GPIO_InitStruct);
    /* CAN2 interrupt Init */
    HAL_NVIC_SetPriority(CAN2_RX0_IRQn, 5, 0);
    HAL_NVIC_EnableIRQ(CAN2_RX0_IRQn);
    HAL_NVIC_SetPriority(CAN2_RX1_IRQn, 5, 0);
    HAL_NVIC_EnableIRQ(CAN2_RX1_IRQn);
  /* USER CODE BEGIN CAN2_MspInit 1 */
@ -187,7 +183,6 @@ void HAL_CAN_MspDeInit(CAN_HandleTypeDef* canHandle)
    /* CAN1 interrupt Deinit */
    HAL_NVIC_DisableIRQ(CAN1_RX0_IRQn);
    HAL_NVIC_DisableIRQ(CAN1_RX1_IRQn);
  /* USER CODE BEGIN CAN1_MspDeInit 1 */
  /* USER CODE END CAN1_MspDeInit 1 */
@ -211,7 +206,6 @@ void HAL_CAN_MspDeInit(CAN_HandleTypeDef* canHandle)
    HAL_GPIO_DeInit(GPIOB, GPIO_PIN_5|GPIO_PIN_6);
    /* CAN2 interrupt Deinit */
    HAL_NVIC_DisableIRQ(CAN2_RX0_IRQn);
    HAL_NVIC_DisableIRQ(CAN2_RX1_IRQn);
  /* USER CODE BEGIN CAN2_MspDeInit 1 */
--- a/Core/Src/stm32f4xx_it.c
+++ b/Core/Src/stm32f4xx_it.c
@ -250,20 +250,6 @@ void CAN1_RX0_IRQHandler(void)
  /* USER CODE END CAN1_RX0_IRQn 1 */
 }
 /**
  * @brief This function handles CAN1 RX1 interrupt.
  */
 void CAN1_RX1_IRQHandler(void)
 {
  /* USER CODE BEGIN CAN1_RX1_IRQn 0 */
  /* USER CODE END CAN1_RX1_IRQn 0 */
  HAL_CAN_IRQHandler(&hcan1);
  /* USER CODE BEGIN CAN1_RX1_IRQn 1 */
  /* USER CODE END CAN1_RX1_IRQn 1 */
 }
 /**
  * @brief This function handles EXTI line[9:5] interrupts.
  */
@ -363,20 +349,6 @@ void DMA2_Stream3_IRQHandler(void)
  /* USER CODE END DMA2_Stream3_IRQn 1 */
 }
 /**
  * @brief This function handles CAN2 RX0 interrupts.
  */
 void CAN2_RX0_IRQHandler(void)
 {
  /* USER CODE BEGIN CAN2_RX0_IRQn 0 */
  /* USER CODE END CAN2_RX0_IRQn 0 */
  HAL_CAN_IRQHandler(&hcan2);
  /* USER CODE BEGIN CAN2_RX0_IRQn 1 */
  /* USER CODE END CAN2_RX0_IRQn 1 */
 }
 /**
  * @brief This function handles CAN2 RX1 interrupt.
  */
--- a/MDK-ARM/.vscode/keil-assistant.log
+++ b/MDK-ARM/.vscode/keil-assistant.log
@ -44,3 +44,19 @@
 [info] Log at : 2025/6/20|09:52:08|GMT+0800
 [info] Log at : 2025/6/20|19:02:32|GMT+0800
 [info] Log at : 2025/6/21|01:54:17|GMT+0800
 [info] Log at : 2025/6/21|09:59:57|GMT+0800
 [info] Log at : 2025/6/21|17:02:34|GMT+0800
 [info] Log at : 2025/6/22|13:36:33|GMT+0800
 [info] Log at : 2025/6/23|15:15:24|GMT+0800
 [info] Log at : 2025/6/23|16:29:17|GMT+0800
 [info] Log at : 2025/6/24|12:24:51|GMT+0800
--- a/MDK-ARM/.vscode/uv4.log
+++ b/MDK-ARM/.vscode/uv4.log
@ -1,4 +1,8 @@
 *** Using Compiler 'V5.06 update 7 (build 960)', folder: 'D:\keil\ARM\ARMCC\Bin'
 Build target 'R1'
 compiling ball.cpp...
 linking...
 Program Size: Code=30768 RO-data=1832 RW-data=260 ZI-data=32244  
 FromELF: creating hex file...
 "R1\R1.axf" - 0 Error(s), 0 Warning(s).
-Build Time Elapsed:  00:00:07
+Build Time Elapsed:  00:00:05
--- a/MDK-ARM/.vscode/uv4.log.lock
+++ b/MDK-ARM/.vscode/uv4.log.lock
@ -1 +1 @@
-2025/6/20 9:52:48
+2025/6/24 2:11:53
--- a/MDK-ARM/R1.uvoptx
+++ b/MDK-ARM/R1.uvoptx
@ -150,7 +150,7 @@
        <SetRegEntry>
          <Number>0</Number>
          <Key>ST-LINKIII-KEIL_SWO</Key>
-          <Name>-U-O142 -O2254 -SF10000 -C0 -A0 -I0 -HNlocalhost -HP7184 -P1 -N00("ARM CoreSight SW-DP (ARM Core") -D00(2BA01477) -L00(0) -TO131090 -TC10000000 -TT10000000 -TP21 -TDS8007 -TDT0 -TDC1F -TIEFFFFFFFF -TIP8 -FO7 -FD20000000 -FC800 -FN1 -FF0STM32F4xx_1024.FLM -FS08000000 -FL0100000 -FP0($$Device:STM32F407IGHx$CMSIS\Flash\STM32F4xx_1024.FLM)</Name>
+          <Name>-U00160029510000164E574E32 -O2254 -SF10000 -C0 -A0 -I0 -HNlocalhost -HP7184 -P1 -N00("ARM CoreSight SW-DP (ARM Core") -D00(2BA01477) -L00(0) -TO131090 -TC10000000 -TT10000000 -TP21 -TDS8007 -TDT0 -TDC1F -TIEFFFFFFFF -TIP8 -FO15 -FD20000000 -FC800 -FN1 -FF0STM32F4xx_1024.FLM -FS08000000 -FL0100000 -FP0($$Device:STM32F407IGHx$CMSIS\Flash\STM32F4xx_1024.FLM)</Name>
        </SetRegEntry>
      </TargetDriverDllRegistry>
      <Breakpoint/>
@ -168,47 +168,17 @@
        <Ww>
          <count>2</count>
          <WinNumber>1</WinNumber>
-          <ItemText>cmd_fromnuc</ItemText>
+          <ItemText>ball,0x0A</ItemText>
        </Ww>
        <Ww>
          <count>3</count>
          <WinNumber>1</WinNumber>
-          <ItemText>nucbuf</ItemText>
+          <ItemText>aaaa,0x0A</ItemText>
        </Ww>
        <Ww>
          <count>4</count>
          <WinNumber>1</WinNumber>
-          <ItemText>goangle,0x0A</ItemText>
+          <ItemText>aaaxxx,0x0A</ItemText>
        </Ww>
        <Ww>
          <count>5</count>
          <WinNumber>1</WinNumber>
          <ItemText>ball,0x0A</ItemText>
        </Ww>
        <Ww>
          <count>6</count>
          <WinNumber>1</WinNumber>
          <ItemText>task_struct,0x0A</ItemText>
        </Ww>
        <Ww>
          <count>7</count>
          <WinNumber>1</WinNumber>
          <ItemText>abc,0x0A</ItemText>
        </Ww>
        <Ww>
          <count>8</count>
          <WinNumber>1</WinNumber>
          <ItemText>ball_state,0x0A</ItemText>
        </Ww>
        <Ww>
          <count>9</count>
          <WinNumber>1</WinNumber>
          <ItemText>triggerCount,0x0A</ItemText>
        </Ww>
        <Ww>
          <count>10</count>
          <WinNumber>1</WinNumber>
          <ItemText>last_ball_state,0x0A</ItemText>
        </Ww>
      </WatchWindow1>
      <Tracepoint>
--- a/MDK-ARM/README.md
+++ b/MDK-ARM/README.md
@ -23,3 +23,14 @@ r1上层
 + 用了将运球和伸缩绑定到一起
 + 串口收数加个滤波
 ## 思路
 + 👆 传球档           👆  配合档  
 + 中  初始档           中  初始档
 + 👇  发射档          👇  运球档
 + 我现在已经收到了运球完成的信号
  + 发射就应该去蓄力接球了
  + 蓄力到位,收到掉落信号和已伸出信号
  + 根据视觉拟合信息的动态调整
  + 拨置👇发射清空掉落信号 (发送归位信号?)
--- a/R1.ioc
+++ b/R1.ioc
@ -21,7 +21,7 @@ CAN2.CalculateTimeQuantum=71.42857142857143
 CAN2.IPParameters=CalculateTimeQuantum,CalculateTimeBit,CalculateBaudRate,BS1,BS2,Prescaler,TXFP,NART
 CAN2.NART=DISABLE
 CAN2.Prescaler=3
-CAN2.TXFP=ENABLE
+CAN2.TXFP=DISABLE
 Dma.Request0=SPI1_RX
 Dma.Request1=SPI1_TX
 Dma.Request2=USART3_RX
@ -181,8 +181,6 @@ MxCube.Version=6.14.1
 MxDb.Version=DB.6.0.141
 NVIC.BusFault_IRQn=true\:0\:0\:false\:false\:true\:false\:false\:false\:false
 NVIC.CAN1_RX0_IRQn=true\:5\:0\:false\:false\:true\:true\:true\:true\:true
 NVIC.CAN1_RX1_IRQn=true\:5\:0\:false\:false\:true\:true\:true\:true\:true
 NVIC.CAN2_RX0_IRQn=true\:5\:0\:false\:false\:true\:true\:true\:true\:true
 NVIC.CAN2_RX1_IRQn=true\:5\:0\:false\:false\:true\:true\:true\:true\:true
 NVIC.DMA1_Stream1_IRQn=true\:5\:0\:false\:false\:true\:true\:false\:true\:true
 NVIC.DMA2_Stream1_IRQn=true\:5\:0\:false\:false\:true\:true\:false\:true\:true
--- a/User/bsp/TopDefine.h
+++ b/User/bsp/TopDefine.h
@ -14,18 +14,17 @@
 #ifndef _AUTO
 #define _AUTO 0
 #endif
 #define TESTUP 1
 #define ONE_CONTROL 0
 //是否使用大疆DT7遥控器
 #ifndef DT7
 #define DT7 0
 #endif
-// //是否使用三摩擦
+
-// #ifndef HANDLING3
+
 // #define HANDLING3 1
 // #endif
 //云台使用类型
 #ifndef GM6020ING
 #define GM6020ING 1
 #endif
 //=============================================
 //================任务通知,时间组================//
 //事件组
@ -35,17 +34,13 @@
 //================任务通知================//
 //运球
 #define BALL_DOWN	(1<<1)
-//接到放球命令
+
 #define PUT_CMD	(1<<2)
 //运球结束 
-#define PUT_OK	(1<<2)
+#define PREPARE (1<<0)
 //伸缩结束
 #define EXTEND_OK	(1<<3)
 #define EXTEND_OK	(1<<5)
 //take任务要等待上面两个标志位
 #define TAKE_WAIT (0x0C)
 //要发送ok了
 #define BALL_SEND (1<<6)
 //能够处理放球命令
--- a/User/device/djiMotor.c
+++ b/User/device/djiMotor.c
@ -66,17 +66,17 @@
 				(ptr)->offset_ecd = (ptr)->ecd;																	\
 		}
- static void VescMotor_Decode(CAN_MotorFeedback_t *feedback, CAN_RxHeaderTypeDef *rx_header, const uint8_t *rx_data)
+//  static void VescMotor_Decode(CAN_MotorFeedback_t *feedback, CAN_RxHeaderTypeDef *rx_header, const uint8_t *rx_data)
- {
+//  {
-          // 检查接收到的ID是否匹配我们期望的VESC状态消息ID
+//           // 检查接收到的ID是否匹配我们期望的VESC状态消息ID
-          // 提取数据字段
+//           // 提取数据字段
-          feedback->rotor_speed = ((int32_t)(rx_data[0]) << 24) | ((int32_t)(rx_data[1]) << 16) | ((int32_t)(rx_data[2]) << 8) | ((int32_t)(rx_data[3]));
+//           feedback->rotor_speed = ((int32_t)(rx_data[0]) << 24) | ((int32_t)(rx_data[1]) << 16) | ((int32_t)(rx_data[2]) << 8) | ((int32_t)(rx_data[3]));
-          feedback->torque_current = ((int16_t)(rx_data[5]) << 8) | (int16_t)(rx_data[4]);
+//           feedback->torque_current = ((int16_t)(rx_data[5]) << 8) | (int16_t)(rx_data[4]);
-          feedback->torque_current /= 1000;  // 将单位从 0.1A 转换为实际电流值
+//           feedback->torque_current /= 1000;  // 将单位从 0.1A 转换为实际电流值
-          feedback->duty_cycle = ((int16_t)(rx_data[7]) << 8) | (int16_t)(rx_data[6]);
+//           feedback->duty_cycle = ((int16_t)(rx_data[7]) << 8) | (int16_t)(rx_data[6]);
-          feedback->duty_cycle /= 1000.0f;  // 将单位从千分之一转换为实际的占空比值 (-1.0 到 1.0)
+//           feedback->duty_cycle /= 1000.0f;  // 将单位从千分之一转换为实际的占空比值 (-1.0 到 1.0)
-  }
+//   }
 //小米
 #define ID_xiaomi 1		
@ -178,23 +178,6 @@ void djiMotorEncode()
 void can2MotorEncode()
 {
  switch (rx_header.ExtId) {
    case CAN_VESC5065_M1_MSG1:
      // 存储消息到对应的电机结构体中
      VescMotor_Decode(&motor_5065[0], &rx_header,rx_data);
      break;
    case CAN_VESC5065_M2_MSG1:
      // 存储消息到对应的电机结构体中
      VescMotor_Decode(&motor_5065[1], &rx_header,rx_data);
     case CAN_VESC5065_M3_MSG1:
      // 存储消息到对应的电机结构体中
      VescMotor_Decode(&motor_5065[2], &rx_header,rx_data);
      break;
    default:
      break;
  }
    switch (rx_data[0]) 
  {
@ -239,6 +222,8 @@ void Dji_Motor_CB()
 void can2_Motor_CB(void)
 {
  HAL_CAN_GetRxMessage(&hcan2, CAN_RX_FIFO1, &rx_header, rx_data);
  //osThreadFlagsSet(thread_alert, EVENT_CAN);
 }
 /**
@ -249,6 +234,9 @@ void can2_Motor_CB(void)
 void djiInit(void)
 {
  thread_alert = osThreadGetId();
  BSP_CAN_RegisterCallback(BSP_CAN_1, HAL_CAN_RX_FIFO0_MSG_PENDING_CB,
                          Dji_Motor_CB);
  BSP_CAN_RegisterCallback(BSP_CAN_2, HAL_CAN_RX_FIFO1_MSG_PENDING_CB,
@ -486,6 +474,27 @@ return DEVICE_OK;
  feedback->can_id = rx_data[0];
 }
 void XiaomiWait_init(int id,CAN_HandleTypeDef*hcan)
 {
    uint32_t send_mail_box;
    tx_message.StdId = id;
    tx_message.IDE = CAN_ID_STD;
    tx_message.RTR = CAN_RTR_DATA;
    tx_message.DLC = 0x08;
 		can_send_data[0] = 0xFF;
 		can_send_data[1] = 0xFF;
 		can_send_data[2] = 0xFF;
 		can_send_data[3] = 0xFF;
 		can_send_data[4] = 0xFF;
 		can_send_data[5] = 0xFF;
 		can_send_data[6] = 0xFF;
 		can_send_data[7] = 0xFC;	
  	HAL_CAN_AddTxMessage(hcan, &tx_message, can_send_data, &send_mail_box);
 }
 void CAN_XiaoMi(int id,JZ_xiaomi_t *JZ_xiaomi,CAN_HandleTypeDef*hcan)
 {
@ -507,12 +516,12 @@ void CAN_XiaoMi(int id,JZ_xiaomi_t *JZ_xiaomi,CAN_HandleTypeDef*hcan)
 		can_send_data[2] = (speed_code >> 4) & 0xFF;  // 速度高8位（取12位中的高8）
 		can_send_data[3] = ((speed_code & 0x0F) << 4) | ((JZ_xiaomi->K_P >> 8) & 0x0F); // 速度低4位 + Kp高4位
-		can_send_data[4] = JZ_xiaomi->K_P  & 0xFF;                 // Kp低8位
+		can_send_data[4] = JZ_xiaomi->K_P  & 0xFF;                 // Kp低8位  位置增益
-		can_send_data[5] = (JZ_xiaomi->K_D  >> 4) & 0xFF;           // Kd高8位（取12位中的高8）
+		can_send_data[5] = (JZ_xiaomi->K_D  >> 4) & 0xFF;           // Kd高8位（取12位中的高8） 位置阻尼
 		can_send_data[6] = ((JZ_xiaomi->K_D & 0x0F) << 4) | ((current_code >> 8) & 0x0F); // Kd低4位 + 电流高4位
-		can_send_data[7] = current_code & 0xFF;       // 电流低8位	
+		can_send_data[7] = current_code & 0xFF;       // 电流低8位	 力矩
 	}
 	else
--- a/User/device/djiMotor.h
+++ b/User/device/djiMotor.h
@ -199,6 +199,7 @@ int8_t CAN_VESC_Control(int id,int speed ,CAN_HandleTypeDef*hcan);
 void Parse_CAN_Response(uint8_t* rx_data, MotorFeedback_t* feedback) ;
 void XiaomiWait_init(int id,CAN_HandleTypeDef*hcan);
 void CAN_XiaoMi(int id,JZ_xiaomi_t *JZ_xiaomi,CAN_HandleTypeDef*hcan);
--- a/User/device/nuc.c
+++ b/User/device/nuc.c
@ -86,7 +86,8 @@ int8_t NUC_RawParse(NUC_t *n) {
      case VISION:
          /* 协议格式 
             0xFF  HEAD
-             0x02  控制帧
+             0x09
               控制帧
             0x01  相机帧
             x    fp32
             y    fp32
--- a/User/lib/calc_lib.c
+++ b/User/lib/calc_lib.c
@ -22,18 +22,18 @@ void user_delay_ms(uint16_t ms)
 	 }
 }
-//¸¡µãÊý·¶Î§ÏÞÖÆ
+// //¸¡µãÊý·¶Î§ÏÞÖÆ
-void abs_limit_fp(fp32 *num, fp32 Limit)
+// void abs_limit_fp(fp32 *num, fp32 Limit)
-{
+// {
-    if (*num > Limit)
+//     if (*num > Limit)
-    {
+//     {
-        *num = Limit;
+//         *num = Limit;
-    }
+//     }
-    else if (*num < -Limit)
+//     else if (*num < -Limit)
-    {
+//     {
-        *num = -Limit;
+//         *num = -Limit;
-    }
+//     }
-}
+// }
 //ÕûÊý·¶Î§ÏÞÖÆ
 void abs_limit_int(int64_t *num, int64_t Limit)
@ -137,3 +137,33 @@ bool is_reached_multiple(float current1, float current2, float current3, float t
    } 
    return false; // 未满足条件达到阈值，返回 0
 }
 //限幅
 void abs_limit_fp(fp32 *num, fp32 Limit)
 {
    if (*num > Limit)
    {
        *num = Limit;
    }
    else if (*num < -Limit)
    {
        *num = -Limit;
    }
 }
 //改原始值，限制最大最小
 fp32 abs_limit_min_max_fp(fp32 *num, fp32 Limit_min,fp32 Limit_max)
 {
    if (*num > Limit_max)
    {
        *num = Limit_max;
        return Limit_max;
    }
    else if (*num < Limit_min)
    {
        *num = Limit_min;
        return Limit_min;
    }
 }
--- a/User/lib/calc_lib.h
+++ b/User/lib/calc_lib.h
@ -34,6 +34,8 @@ float expo_map(float value, float expo_factor);
 bool is_reached_multiple(float current1, float current2, float current3, float target1, float target2, float target3, float mistake, int threshold);
 fp32 abs_limit_min_max_fp(fp32 *num, fp32 Limit_min,fp32 Limit_max);
 #ifdef __cplusplus
 }
 #endif
--- a/User/module/ball.cpp
+++ b/User/module/ball.cpp
@ -7,13 +7,10 @@
 #include "shoot.hpp"
 extern RC_ctrl_t rc_ctrl;
 extern int key;
 //伸缩
-#define I_ANGLE 0
+#define I_ANGLE 147
-#define O_ANGLE 140
+#define O_ANGLE 187
 //PE11 气缸
@ -25,12 +22,20 @@ Ball ::Ball()
    feedback=get_CyberGear_point();
    //小米电机初始化
-    xiaomi.position = 0;    // 
+    xiaomi.position = I_ANGLE;    // 
-    xiaomi.speed    = 20;   // 
+    xiaomi.speed    = 25;   // 
-    xiaomi.K_P      = 100;  // 
+    xiaomi.K_P      = 80;  // 位置增益
-    xiaomi.K_D      =20;    // 
+    xiaomi.K_D      =20;    // 位置阻尼
-    xiaomi.K_C      = 2 ;  
+    xiaomi.K_C      = 50 ;  // 力矩
-    xiaomi.Pmax     =1;
+    xiaomi.Pmax     =1; //好像没啥用
    // //小米电机初始化
    // xiaomi.position = 0;    // 
    // xiaomi.speed    = 0;   // 
    // xiaomi.K_P      = 0;  // 
    // xiaomi.K_D      =0;    // 
    // xiaomi.K_C      = 0 ;  
    // xiaomi.Pmax     =0;
    //状态机状态初始化
    currentState1= BALL_IDLE;
@ -68,7 +73,15 @@ void Ball::rc_mode()
 }
-#if TESTBALL
+void Ball::Send_control()
 {
    CAN_XiaoMi(1,&xiaomi,&hcan2);
    osDelay(1);
 }
 #if TESTUP
 void Ball::ballDown(void)
 {
@ -82,11 +95,11 @@ void Ball::Move_Extend()
 {
    if(extern_key==IN)
    {
-        xiaomi.position = 0;
+        xiaomi.position = I_ANGLE;
    }
    if(extern_key==OUT)
    {
-        xiaomi.position = 90;
+        xiaomi.position = O_ANGLE;
    }
 }
@ -124,16 +137,6 @@ void Ball::ball_control()
 }
 void Ball::Send_control()
 {
    CAN_XiaoMi(1,&xiaomi,&hcan2);
    osDelay(1);
 }
 int ball_state = 0;
 int triggerCount = 0; // 光电传感器触发计数
 int last_ball_state = 1; // 上一次的光电状态
@ -146,9 +149,8 @@ void Ball::ballHadling(void)
    case BALL_IDLE:
       HAL_GPIO_WritePin(PAW_GPIO_Port, PAW_Pin, GPIO_PIN_RESET); //确保爪气缸关闭 
       HAL_GPIO_WritePin(DOWN_GPIO_Port, DOWN_Pin, GPIO_PIN_RESET); // 确保下气缸关闭 
-        if (key > 0 ||rc_key == DOWN2) // 检测按键是否被按下
+        if (rc_key == DOWN2) // 检测按键是否被按下
        {
            key = 0; // 重置按键状态
            triggerCount = 0; // 重置触发计数
            currentState1 = BALL_FORWARD; 
        }
@ -177,7 +179,6 @@ void Ball::ballHadling(void)
        break;
        case BALL_FLAG:
        osDelay(10); // 延时 50ms
        if (triggerCount == 1 && ball_state == 0 && last_ball_state == 1) // 第二次检测到球
        {
            triggerCount++; // 增加触发计数
@ -189,7 +190,7 @@ void Ball::ballHadling(void)
    case BALL_CLOSE:
        if (triggerCount == 2) // 确保是第二次触发
        {
-            osDelay(50); 
+            //osDelay(5); 
            HAL_GPIO_WritePin(PAW_GPIO_Port, PAW_Pin, GPIO_PIN_RESET); // 闭合气缸爪子
            currentState1 = BALL_FINISH; // 切换到反转状态
        }
@ -199,7 +200,6 @@ void Ball::ballHadling(void)
        osDelay(50); // 延时 50ms
        HAL_GPIO_WritePin(PAW_GPIO_Port, PAW_Pin, GPIO_PIN_RESET); // 确保气缸爪子闭合
        HAL_GPIO_WritePin(DOWN_GPIO_Port, DOWN_Pin, GPIO_PIN_RESET); // 确保下气缸关闭
        key = 0; // 重置按键状态
        triggerCount = 0; // 重置触发计数
        //currentState1 = BALL_IDLE; // 回到空闲状态
@ -218,63 +218,6 @@ void Ball::ballHadling(void)
 #if ONE_CONTROL
 //任务通知来作全过程
 void Ball::ballDown(void)
 {
    xiaomi.position = I_ANGLE; 
    if(feedback->position_deg== I_ANGLE) // 确保伸缩电机到位
    {
        HAL_GPIO_WritePin(PAW_GPIO_Port, PAW_Pin, GPIO_PIN_SET); // 打开气缸爪子
        HAL_GPIO_WritePin(DOWN_GPIO_Port, DOWN_Pin, GPIO_PIN_RESET); // 确保下气缸关闭
    }
    if(ball_state==0)//检测到球
    {
         osThreadFlagsSet(task_struct.thread.ball, BALL_DOWN);
         //osThreadFlagsSet(task_struct.thread.shoot, BALL_DOWN);
         xiaomi.position = O_ANGLE; 
    }
    if(hand_thread & BALL_DOWN)
    {
        if(feedback->position_deg== O_ANGLE)
        {
          osThreadFlagsSet(task_struct.thread.shoot, EXTEND_OK);  //告诉发射球出去了
          osThreadFlagsSet(task_struct.thread.ball, EXTEND_OK);  //告诉发射球出去了
        }
    }
 }
 void Ball::Idle_control()
 {
       HAL_GPIO_WritePin(PAW_GPIO_Port, PAW_Pin, GPIO_PIN_RESET); //确保爪气缸关闭 
       HAL_GPIO_WritePin(DOWN_GPIO_Port, DOWN_Pin, GPIO_PIN_RESET); // 确保下气缸关闭 
       if(hand_thread & EXTEND_OK)
       {
         xiaomi.position = O_ANGLE; // 伸缩电机伸出去
       }
       else
       {
         xiaomi.position = I_ANGLE; // 伸缩电机回位,底盘可能跑的更好
       }
        if (currentState1 == BALL_FINISH)
        {
            currentState1 = BALL_IDLE;
        }
        else {
             currentState1 = BALL_IDLE; // 默认回到空闲状态
        }
 }
 void Ball::ball_control()
 {
    hand_thread = osThreadFlagsGet(); // 获取任务通知标志位
@ -290,8 +233,8 @@ void Ball::ball_control()
        break;
       case DOWN2: 
         osThreadFlagsSet(task_struct.thread.shoot, PREPARE); // 通知发射任务快点去蓄力
         ballHadling();
        break;
    }
@ -301,14 +244,62 @@ void Ball::ball_control()
 }
-void Ball::Send_control()
+//任务通知来作全过程
 void Ball::ballDown(void)
 {
    switch(currentState1)
    {
        case BALL_IDLE:
            xiaomi.position = I_ANGLE; // 保持收回
            if(feedback->position_deg >= I_ANGLE-0.8 && feedback->position_deg <= I_ANGLE+0.8)
            {
                currentState1 = EXTEND_DOWN;
            }
            break;
-    CAN_XiaoMi(1,&xiaomi,&hcan2);
+        case EXTEND_DOWN:
-    osDelay(1);
+            HAL_GPIO_WritePin(PAW_GPIO_Port, PAW_Pin, GPIO_PIN_SET);
            HAL_GPIO_WritePin(DOWN_GPIO_Port, DOWN_Pin, GPIO_PIN_RESET);
            // 检测到球自由下落一次就切换状态
            if(ball_state == 0)
            {
                currentState1 = EXTEND_OUT;
            }
            break;
        case EXTEND_OUT:
            xiaomi.position = O_ANGLE; // 保持伸出
            if(feedback->position_deg >= O_ANGLE-0.2 && feedback->position_deg <= O_ANGLE+0.2)
            {
                osThreadFlagsSet(task_struct.thread.shoot, EXTEND_OK);
                currentState1 = EXTEND_FINISH; // 保持伸出，直到拨杆复位
            }
            break;
        case EXTEND_FINISH:
            xiaomi.position = O_ANGLE; // 一直保持伸出
            // 等待拨杆复位（如切到MIDDLE2），Idle_control会负责回位
            break;
        default:
            currentState1 = BALL_IDLE;
            break;
    }
 }
 void Ball::Idle_control()
 {
    HAL_GPIO_WritePin(PAW_GPIO_Port, PAW_Pin, GPIO_PIN_RESET); // 确保爪气缸关闭 
    HAL_GPIO_WritePin(DOWN_GPIO_Port, DOWN_Pin, GPIO_PIN_RESET); // 确保下气缸关闭 
    osThreadFlagsClear(PREPARE);
    osThreadFlagsClear(EXTEND_OK);
    // 拨杆回到中间挡位时，回位并重置状态机
    xiaomi.position = I_ANGLE;
    currentState1 = BALL_IDLE;
 }
 int ball_state = 0;
 int triggerCount = 0; // 光电传感器触发计数
@ -322,12 +313,16 @@ void Ball::ballHadling(void)
    case BALL_IDLE:
       HAL_GPIO_WritePin(PAW_GPIO_Port, PAW_Pin, GPIO_PIN_RESET); //确保爪气缸关闭 
       HAL_GPIO_WritePin(DOWN_GPIO_Port, DOWN_Pin, GPIO_PIN_RESET); // 确保下气缸关闭 
-        if (key > 0 ||rc_key == DOWN2) // 检测按键是否被按下
+        if (rc_key == DOWN2)
        {   
-            key = 0; // 重置按键状态
+            xiaomi.position = O_ANGLE;//外伸       
            triggerCount = 0; // 重置触发计数
            if(feedback->position_deg>= O_ANGLE-1)// 确保伸缩电机到位
            {
                 currentState1 = BALL_FORWARD; 
            }
        }
        break;
    case BALL_FORWARD:
@ -342,7 +337,6 @@ void Ball::ballHadling(void)
        HAL_GPIO_WritePin(DOWN_GPIO_Port, DOWN_Pin, GPIO_PIN_RESET); // 关闭下气缸
        if (ball_state == 0 && last_ball_state == 1) // 检测到状态从无球变为有球
        {
            //osDelay(10); // 延时去抖动
            triggerCount++; // 增加触发计数
            if (triggerCount == 1) // 第一次触发
            {
@ -353,7 +347,7 @@ void Ball::ballHadling(void)
        break;
        case BALL_FLAG:
-        osDelay(10); // 延时 50ms
+       // osDelay(10); // 延时 50ms
        if (triggerCount == 1 && ball_state == 0 && last_ball_state == 1) // 第二次检测到球
        {
            triggerCount++; // 增加触发计数
@ -375,10 +369,8 @@ void Ball::ballHadling(void)
        osDelay(50); // 延时 50ms
        HAL_GPIO_WritePin(PAW_GPIO_Port, PAW_Pin, GPIO_PIN_RESET); // 确保气缸爪子闭合
        HAL_GPIO_WritePin(DOWN_GPIO_Port, DOWN_Pin, GPIO_PIN_RESET); // 确保下气缸关闭
        key = 0; // 重置按键状态
        triggerCount = 0; // 重置触发计数
-        //currentState1 = BALL_IDLE; // 回到空闲状态
+        triggerCount = 0; // 重置触发计数
        break;
--- a/User/module/ball.hpp
+++ b/User/module/ball.hpp
@ -11,22 +11,23 @@
 #include "filter.h"
 #include "calc_lib.h"
-#define TESTBALL 0
+
 #define ONE_CONTROL 1
 // 定义状态枚举
 typedef enum {
    BALL_IDLE,         // 空闲状态
    BALL_FORWARD,      // 
    BALL_DROP,         // 
    BALL_REVERSE,      //
    BALL_FLAG,
    BALL_CLOSE,         // 关闭状态
    BALL_FINISH,        // 完成状态
  //持球状态
    BALL_TAKE,
-    BALL_LOSE
+    EXTEND_DOWN,
    EXTEND_OUT,
    EXTEND_FINISH,
    BALL_LOSE,
 } BallState_t;
@ -64,7 +65,7 @@ public:
    void Extend_mcontrol(int angle1,int angle2);
    void ball_control(void);
-    BallState_t currentState1; // 当前状态
+    BallState_t currentState1; // 运球任务状态机
      int flag_thread;//暂时还没用到
 	  int ball_state ;//光电检测
--- a/User/module/shoot.cpp
+++ b/User/module/shoot.cpp
@ -22,12 +22,16 @@ NUC_t nuc_v;
 //尽量别动这组pid
 const fp32 Shoot:: M2006_speed_PID[3] = {5, 0, 0.01};
-const fp32 Shoot:: M2006_angle_PID[3] = { 25, 0.1, 0};
+const fp32 Shoot:: M2006_angle_PID[3] = { 15, 0.1, 0};
 #define TO_TOP 10.0f
 #define TO_BOTTOM 5.0f
 #define INIT_POS -130
 #define TOP_POS -210
 #define BOTTOM_POS 0
 #define GO_ERROR 1.0f 
-#define Tigger_DO -10  
+#define Tigger_DO 0  
 #define Tigger_ZERO 100 
 #define Tigger_ERROR 3
@ -61,6 +65,7 @@ Shoot::Shoot()
    currentState= SHOOT_IDLE;
    LowPassFilter2p_Init(&distance_filter,500.0f,80.0f); //给distance 做滤波
 }
@ -78,7 +83,8 @@ void Shoot::trigger_control()
 void Shoot :: distanceGet(const NUC_t &nuc_v)
 {
-    distance=nuc_v.vision.x; // 获取自瞄数据
+    distance= LowPassFilter2p_Apply(&distance_filter, nuc_v.vision.x); // 对视觉距离进行滤波处理
    //distance=nuc_v.vision.x; // 获取自瞄数据
 }
@ -151,22 +157,41 @@ void Shoot::rc_mode()
    //   trigger_key=SHOOT;  
    // }
-    //knob_increment=rc_ctrl.ch[2]/150;
+    // //旋钮增量
    // static int last_knob_value = 0; // 记录旋钮的上一次值
    // int current_knob_value = rc_ctrl.sw[7]; // 获取当前旋钮值
-    //旋钮增量
+    // // 计算旋钮增量
-    static int last_knob_value = 0; // 记录旋钮的上一次值
+    // if (current_knob_value >= 200 && current_knob_value <= 1800) {
-    int current_knob_value = rc_ctrl.sw[7]; // 获取当前旋钮值
+    //     knob_increment = (current_knob_value - last_knob_value) / 15.0f; // 每80单位对应一个增量
    // } else {
    //     knob_increment = 0; // 如果旋钮值超出范围，不产生增量
    // }
-    // 计算旋钮增量
+    // 旋钮物理范围
-    if (current_knob_value >= 200 && current_knob_value <= 1800) {
+const int knob_min = 200;
-        knob_increment = (current_knob_value - last_knob_value) / 15.0f; // 每80单位对应一个增量
+const int knob_max = 1800;
-    } else {
+
-        knob_increment = 0; // 如果旋钮值超出范围，不产生增量
+// 目标映射范围
-    }
+const float map_min = 130.0f;
 const float map_max = -60.0f;
 int current_knob_value = rc_ctrl.sw[7];
 // 限制范围
 if (current_knob_value < knob_min) current_knob_value = knob_min;
 if (current_knob_value > knob_max) current_knob_value = knob_max;
 // 线性映射
 knob_increment = map_min + (map_max - map_min) * (current_knob_value - knob_min) / (knob_max - knob_min);
 }
 #if TESTUP
 void Shoot::shoot_control() {
    //方便调试
@ -181,13 +206,13 @@ void Shoot::shoot_control() {
        control_pos = INIT_POS; // 默认中间挡位位置     
        go1.Pos = fire_pos; // 设置蓄力电机位置
-        t_posSet = Tigger_ZERO; // 扳机松开
+        //t_posSet = Tigger_ZERO; // 扳机松开
        if (currentState == SHOOT_READY) {
            // 如果当前状态是准备发射，松开钩子发射
            t_posSet = Tigger_ZERO; // 扳机扣动
            BSP_Buzzer_Stop();
-            if (t_posSet >= 95) { // 假设120度为发射完成角度
+            if (t_posSet >= Tigger_ZERO-20) { // 假设120度为发射完成角度
                currentState = SHOOT_IDLE; // 切换到空闲状态
                is_hooked = false; // 重置钩子状态
            }
@ -216,16 +241,14 @@ break;
       case DOWN1:
        control_pos = INIT_POS; // 默认中间挡位位置
        //fire_pos = control_pos + knob_increment; // 根据旋钮值调整发射位置
        //fire_pos = control_pos + knob_increment; // 根据旋钮值调整发射位置
        go1.Pos = fire_pos; // 设置蓄力电机位置
-        t_posSet = Tigger_ZERO; // 扳机松开
+        //t_posSet = Tigger_ZERO; // 扳机松开
        if (currentState == SHOOT_READY) {
            // 如果当前状态是准备发射，松开钩子发射
            t_posSet = Tigger_ZERO; // 扳机扣动
            BSP_Buzzer_Stop();
-            if (t_posSet >= 95) { // 假设120度为发射完成角度
+            if (t_posSet >= Tigger_ZERO-20) { // 假设120度为发射完成角度
                currentState = SHOOT_IDLE; // 切换到空闲状态
                is_hooked = false; // 重置钩子状态
            }
@ -253,6 +276,8 @@ break;
    }     
    abs_limit_min_max_fp(&go1.Pos ,-210.0f,2.0f);
    // 发送数据到蓄力电机
    GO_SendData(go1.Pos, 5.0f);
@ -276,7 +301,7 @@ void Shoot :: shoot_Current()
        case SHOOT_TOP:
            t_posSet = Tigger_DO; // 扳机扣动钩住
-            if (trigger_Motor->total_angle<-6) 
+            if (trigger_Motor->total_angle<Tigger_DO+1.0f && trigger_Motor->total_angle>Tigger_DO-1.0f) 
            { 
                //判定为钩住
                is_hooked = true; // 标记钩子已钩住
@ -322,3 +347,180 @@ void Shoot::RemoveError() {
     go1.Pos = control_pos;
 }
 #endif
 #if ONE_CONTROL
 void Shoot::shoot_control() {
 //方便调试 反馈信息
 feedback.fd_gopos = go1_data->Pos; 
 feedback.fd_tpos = trigger_Motor->total_angle;
 shoot_thread = osThreadFlagsGet(); // 获取任务通知标志位
 switch (mode_key)
    {
    case VSION:
      fire_pos = distance; // 视觉拟合的力
      switch (rc_key) {
       case MIDDLE1:
        if(shoot_thread & PREPARE) // 如果收到放球完成的通知
        {
            ball_receive(); // 执行接收球的操作
        }
        if(shoot_thread & EXTEND_OK) // 如果收到伸缩完成的通知
        {
            go1.Pos = fire_pos; // 设置蓄力电机位置
            if(feedback.fd_gopos >= fire_pos - GO_ERROR && feedback.fd_gopos <= fire_pos + GO_ERROR)
            {
             BSP_Buzzer_Start();			
             BSP_Buzzer_Set(1,5000);
            }
        }
        break;
    case DOWN1:
    if(shoot_thread & EXTEND_OK)
       {
        BSP_Buzzer_Stop();
        t_posSet = Tigger_ZERO; // 扳机扣动 射出
        currentState = SHOOT_IDLE; // 默认回到空闲状态
        osThreadFlagsClear(EXTEND_OK);
       }
        break;
    case UP1:
       RemoveError();
        break;
    default:
        break;
    }
 break;
 //无自瞄拟合测试档
   case TEST:
    switch (rc_key) {
       case MIDDLE1:
        if(shoot_thread & PREPARE) // 如果收到放球完成的通知
        {
            ball_receive(); // 执行接收球的操作
        }
        if(shoot_thread & EXTEND_OK) // 如果收到伸缩完成的通知
        {
            fire_pos = INIT_POS + knob_increment; // 根据旋钮值调整发射位置
            go1.Pos = fire_pos; // 设置蓄力电机位置
            if(feedback.fd_gopos >= fire_pos - GO_ERROR && feedback.fd_gopos <= fire_pos + GO_ERROR)
            {
             BSP_Buzzer_Start();			
             BSP_Buzzer_Set(1,5000);
            }
        }
        break;
    case DOWN1:
    if(shoot_thread & EXTEND_OK)
       {
        BSP_Buzzer_Stop();
        t_posSet = Tigger_ZERO; // 扳机扣动 射出
        currentState = SHOOT_IDLE; // 默认回到空闲状态
        osThreadFlagsClear(EXTEND_OK);     
       }
        break;
    case UP1:
       RemoveError();
        break;
    default:
        break;
    }
 break;       
    default:
        break;
    }     
    abs_limit_min_max_fp(&go1.Pos ,-210.0f,2.0f);
    // 发送数据到蓄力电机
    GO_SendData(go1.Pos, limit_speed);
    // 控制扳机电机
    trigger_control();
 }
 //配合运球到发射
 void Shoot ::ball_receive()
 {
    switch (currentState) 
    {
        case SHOOT_IDLE:
            // 初始状态：钩子移动到顶部，钩住拉簧
            control_pos = TOP_POS;   
            limit_speed=TO_TOP;//快速上去      
            t_posSet = Tigger_ZERO;
            if(feedback.fd_gopos >= TOP_POS - 0.5f && feedback.fd_gopos <= TOP_POS + 0.5f)
            {
                currentState = GO_TOP; // 切换到准备发射状态
            }
            break;
       case GO_TOP:
            t_posSet = Tigger_DO;
            if (trigger_Motor->total_angle<Tigger_DO+1.0f && trigger_Motor->total_angle>Tigger_DO-1.0f) 
            { 
                currentState = BAKC;    // 切换到准备发射状态
            }
            break;  
       case BAKC:
            control_pos = BOTTOM_POS; 
            limit_speed=TO_BOTTOM;//慢速下来  
            if(feedback.fd_gopos >= BOTTOM_POS - 1.0f && feedback.fd_gopos <= BOTTOM_POS + 1.0f)
            {
                osThreadFlagsClear(PREPARE); // 清除任务通知标志位
            }
            break; 
    }
   //调整go电机位置
     go1.Pos = control_pos;
 }
 void Shoot::RemoveError() {
    currentState = SHOOT_IDLE;
    control_pos = TOP_POS;
    if (feedback.fd_gopos >= control_pos - 0.5f&& feedback.fd_gopos<= control_pos + 0.5f)
    {
        t_posSet = Tigger_ZERO; 
        is_hooked = false; 
    }
    if(trigger_Motor->total_angle>=Tigger_ZERO-10)
    {
        //认为完全松开
         control_pos=INIT_POS;
         BSP_Buzzer_Stop();
    }
     go1.Pos = control_pos;
 }
 #endif
--- a/User/module/shoot.hpp
+++ b/User/module/shoot.hpp
@ -5,6 +5,7 @@
 #include "GO_M8010_6_Driver.h"
 #include "nuc.h"
 #include "usart.h"
 #include "filter.h"
 // 定义状态枚举
 typedef enum {
@ -14,7 +15,10 @@ typedef enum {
    SHOOT_READY,      
    SHOOT_WAIT,
    SHOOT_FIRE,        // 发射状态
-    SHOOT_RETURN       // 自动返回状态
+    SHOOT_RETURN,       // 自动返回状态
    //运射配合
    GO_TOP,
    BAKC
 } ShootState_t;
 // // 定义状态枚举
@ -52,7 +56,7 @@ public:
    void shoot_control(void);
    void shoot_Current(void); 
    void RemoveError(void);
-   
+    void ball_receive(void);
    int GO_SendData(float pos,float limit);
@ -68,7 +72,6 @@ public:
     }feedback;
    //扳机
    float speed_trigger;
    int16_t result;
@ -77,13 +80,16 @@ public:
    float fd_tpos; //扳机反馈位置
    motor_measure_t *trigger_Motor;
    //滤波器
    LowPassFilter2p_t distance_filter; // 用于滤波视觉距离
    //==========================公共变量==========================
    int16_t rc_key; //遥控器按键
    int16_t mode_key;
    int16_t trigger_key;
    ShootState_t currentState; //状态机
-    //volatile BallState_t ballStatus;//是否有球
+
-    volatile uint32_t flag_thread;//接收传回的线程通知
+    volatile uint32_t shoot_thread;//接收传回的线程通知
    fp32 distance;   //视觉距离
 private:
@ -98,6 +104,7 @@ private:
    bool is_hooked;// 标记钩子是否已经钩住拉簧
    float limit_speed;//go电机限速
 };
--- a/User/task/ballTask.cpp
+++ b/User/task/ballTask.cpp
@ -12,6 +12,7 @@ Ball ball;
 //检查光电
 int abc=0;
 int aaaa=146;
 extern int speedm;
@ -20,6 +21,10 @@ void FunctionBall(void *argument)
    (void)argument; /* 未使用argument，消除警告 */
    const uint32_t delay_tick = osKernelGetTickFreq() / TASK_FREQ_BALL;
 		osDelay(6000);//等待极致控制板启动
    XiaomiWait_init(1,&hcan2); //小米电机初始化
    uint32_t tick = osKernelGetTickCount();
    while(1)
@ -34,6 +39,8 @@ void FunctionBall(void *argument)
    ball.ball_control(); // 控制球的动作    
    // ball.xiaomi.position = aaaa; 
    // CAN_XiaoMi(1,&ball.xiaomi,&hcan2);
    tick += delay_tick; /* 计算下一个唤醒时刻 */
    osDelayUntil(tick);
--- a/User/task/nucTask.cpp
+++ b/User/task/nucTask.cpp
@ -23,6 +23,8 @@ void Function_nuc(void *argument)
    NUC_Init(&cmd_fromnuc);
    HAL_GPIO_WritePin(LED_G_GPIO_Port,LED_G_Pin,GPIO_PIN_SET);
   uint32_t tick = osKernelGetTickCount();
    while(1)
--- a/User/task/shootTask.cpp
+++ b/User/task/shootTask.cpp
@ -10,7 +10,7 @@ extern RC_ctrl_t rc_ctrl;
 Shoot shoot;
 NUC_t nucData; // 自瞄
-int goangle=0;
+int aaaxxx=0;
 void FunctionShoot(void *argument)
 {
@ -27,13 +27,6 @@ while(1)
 #endif
 	shoot.rc_mode(); //遥控器模式
 	//我放的任务通知 运球成功放置过来后
 	shoot.flag_thread=osThreadFlagsGet();
 	if(shoot.flag_thread & BALL_DOWN)
 	{
 	}
 	if (osMessageQueueGet(task_struct.msgq.nuc, &nucData, NULL, 0) == osOK)
 	{
@ -41,6 +34,9 @@ while(1)
 	}
 	shoot.shoot_control();
 //	shoot.t_posSet=aaaxxx;
 //	shoot.trigger_control();
 //  shoot.GO_SendData(goangle,5);
 //  shoot.shoot_control();
 //	shoot.t_posSet=goangle;