WO2023279656A1 - 一种实现红外数据、温感数据和其他数据的传输方法 - Google Patents
一种实现红外数据、温感数据和其他数据的传输方法 Download PDFInfo
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F15/00—Digital computers in general; Data processing equipment in general
- G06F15/16—Combinations of two or more digital computers each having at least an arithmetic unit, a program unit and a register, e.g. for a simultaneous processing of several programs
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- H04N23/67—Focus control based on electronic image sensor signals
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- the invention relates to the technical field of infrared online temperature measurement, in particular to a transmission method for realizing infrared data, temperature sensing data and other data.
- ARM A 32-bit Reduced Instruction Set (RISC) processor architecture ARM processors are widely used in many embedded system designs. ARM processors are characterized by fixed instruction length, high execution efficiency, and low cost.
- RISC Reduced Instruction Set
- the FPGA After the FPGA completes the data acquisition and processing, it transmits the infrared data through the camera interface, and uses the ARM camera interface to receive the infrared data, and the temperature sensing data, detector data, The position information of the block, the lens information, the gear switch, the focal length of the lens and other data, the ARM terminal program actively queries or passively receives through the IIC or TTL serial port.
- the purpose of the present invention is to provide a method for transmitting infrared data, temperature sensing data and other data, so as to solve the problem of mode switching control between the ARM processor and FPAG proposed in the background technology, gear state update, electric or manual adjustment, etc.
- the receiving process cannot be performed in real time, and there will be a problem of "black screen" when the TV channel changes.
- a method for transmitting infrared data, temperature sensing data and other data including a processor box and a data information acquisition unit, the inside of the processor box is equipped with a control circuit board, the inside of the control circuit board is respectively equipped with a data packaging module, a data sending module, a data receiving module, a data unpacking module, a temperature measurement processing module and an image processing module, and the output terminal of the data information acquisition unit is connected with the data packaging module
- the input terminals are electrically connected, the output terminals of the data packaging module are electrically connected to the input terminals of the data sending module, and the output terminals of the data sending module are electrically connected to the input terminals of the data receiving module.
- the output end of the data receiving module is electrically connected to the input end of the data unpacking module
- the output end of the data unpacking module is electrically connected to the input end of the temperature measurement processing module
- the output of the temperature measurement processing module The terminal is electrically connected to the input terminal of the image processing module.
- the upper end of the processor box is fixedly connected with a display screen through a control rod, and four communication interfaces are arranged on the front surface of the processor box.
- the front surface of the processor box is provided with a power inlet hole, a data transmission interface, an audio output interface and a power switch.
- the data information collection unit includes infrared data information, temperature measurement gear data information, temperature sensing data information, focal length position data information, lens information and block position information.
- the FPGA end repacks the infrared data and other data and adjusts the data output array, and the ARM end unpacks after receiving a frame of data to complete.
- the infrared data information is the collected detector AD value array data
- the temperature measurement gear data information is manual switching or FPGA realizes automatic switching according to the algorithm
- the focal length position data information will be real-time due to manual focusing or electric focusing Change.
- the present invention can technically improve the real-time performance of infrared data processing and temperature measurement calculation at the ARM end, improve the effectiveness of each frame of infrared data processing, and reduce the risk of active query through IIC or TTL. Or CPU usage caused by passive reception.
- the data information acquisition unit collects infrared data information, temperature measurement gear data information, temperature sensing data information, focal length position data information, lens information and block position information, and performs unified integration by packaging the data information Send, and then receive and unpack the data.
- the temperature measurement processing module is used to measure and detect the temperature of the device in real time.
- the image processing module is used for imaging display.
- the ARM processor and FPAG are used for mode switching control, gear status update, electric Or when manually adjusting the focus, it can receive and process in real time, which solves the problem of real-time synchronous transmission of infrared data, temperature sensing value, shutter position, focal length value, temperature measurement gear and other data between the ARM end and the FPGA, which can improve The interactive experience of device user operation.
- FIG. 1 is a schematic structural diagram of a processor box of the present invention.
- Fig. 2 is a schematic structural diagram of the control circuit board of the present invention.
- Fig. 3 is a functional block diagram of the present invention.
- a method for transmitting infrared data, temperature sensing data and other data including a processor box 3 and a data information acquisition unit 16, the processor box 3
- the inside of the control circuit board 9 is equipped with a control circuit board 9, and the inside of the control circuit board 9 is respectively equipped with a data packaging module 12, a data sending module 11, a data receiving module 10, a data unpacking module 14, a temperature measurement processing module 15 and an image processing module 13,
- the output end of the data information acquisition unit 16 is electrically connected to the input end of the data packing module 12, and the output end of the data packing module 12 is electrically connected to the input end of the data sending module 11.
- the data sending module 11 The output terminal of the data receiving module 10 is electrically connected to the input terminal of the data receiving module 10, the output terminal of the data receiving module 10 is electrically connected to the input terminal of the data unpacking module 14, and the output terminal of the data unpacking module 14 is connected to the input terminal of the data receiving module 14.
- the input ends of the temperature measurement processing module 15 are electrically connected, and the output ends of the temperature measurement processing module 15 are electrically connected to the input ends of the image processing module 13 .
- the upper end of the processor box 3 is fixedly connected with the display screen 1 through the control rod 2 , and four communication interfaces 4 are arranged on the front surface of the processor box 3 .
- the front surface of the processor box 3 is provided with a power inlet 5 , a data transmission interface 6 , an audio output interface 7 and a power switch 8 .
- the data information collection unit 16 includes infrared data information, temperature measurement gear data information, temperature sensing data information, focal length position data information, lens information and shutter position information.
- the FPGA end repacks the infrared data and other data and adjusts the data output array, and the ARM end receives a frame of data and unpacks it to complete.
- the infrared data information is the collected detector AD value array data
- the temperature measurement gear data information is manual switching or FPGA realizes automatic switching according to the algorithm
- the focal length position data information will be changed in real time due to manual or electric focusing.
- the data information acquisition unit 16 includes infrared data information, temperature measurement gear data information, temperature sensing data information, focal length position data information, lens information and block position information
- the data information acquisition unit 16 collect infrared data information, temperature measurement gear data information, temperature sensing data information, focal length position data information, lens information and shutter position information
- the output end of the data information acquisition unit 16 and the input end of the data packaging module 12 are electrically connected between the output end of the data packing module 12 and the input end of the data sending module 11, and the data packing module 12 and the data sending module 11 carry out unified integrated sending by packing the data information
- the output end of the data sending module 11 is electrically connected to the input end of the data receiving module 10, and is electrically connected between the output end of the data receiving module 10 and the input end of the data unpacking module
- the output end is electrically connected to the input end of the image processing module 13, and the imaging display is performed through the image processing module 13, and when mode switching control, gear position status update, electric or manual focusing are performed through the ARM processor and FPAG, It can receive and process in real time, which solves the problem of real-time synchronous transmission of infrared data, temperature sensor value, shutter position, focal length value, temperature measurement gear and other data between the ARM terminal and FPGA, and can improve the interactive experience of device user operations.
- the present invention can technically improve the real-time performance of infrared data processing and temperature measurement calculation at the ARM end in the field of infrared temperature measurement equipment as a whole, improves the effectiveness of each frame of infrared data processing, and reduces the risk of active or passive queries due to IIC or TTL. CPU usage caused by reception.
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Abstract
本发明公开了一种实现红外数据、温感数据和其他数据的传输方法,所述处理器机盒的内部安装有控制电路板,所述数据信息采集单元的输出端与数据打包模块的的输入端之间通过电性连接,数据发送模块的输出端与数据接收模块的输入端之间通过电性连接,数据接收模块的输出端与数据解包模块的输入端之间通过电性连接,数据解包模块的输出端与测温处理模块的输入端之间通过电性连接,测温处理模块的输出端与图像处理模块的输入端之间通过电性连接。本发明可以在红外测温设备领域整体从技术上提升ARM端处理红外数据和测温计算的实时性,提高了每帧红外数据处理的有效性,降低因为通过IIC或TTL进行主动查询或则被动接收导致的CPU占用率。
Description
本发明涉及红外在线测温技术领域,具体为一种实现红外数据、温感数据和其他数据的传输方法。
ARM一个32位元精简指令集(RISC)处理器架构,ARM处理器广泛地使用在许多嵌入式系统设计。ARM处理器的特点有指令长度固定,执行效率高,低成本等。目前的红外设备中,FPGA完成了数据采集和处理后,通过摄像头接口传输红外数据,利用ARM的摄像头接口来接收红外数据,而FPGA采集的测温处理所需的温感数据、探测器数据、挡片位置信息、镜头信息、档位切换、镜头焦距等数据,ARM端程序通过IIC或则TTL串口进行主动查询或者被动接收。
这些接口数据的更新因为本身的速率限制,无法和摄像头接口的传输帧率匹配,导致红外数据更新N帧后,这些数据才会得到更新。这种红外数据和其他数据通信方式,ARM处理器与FPAG进行模式切换控制、档位状态更新、电动或则手动调焦时,无法实时进行接收处理,会出现电视换台的“黑屏”现象。因此急需研究一种实现红外数据、温感数据和其他数据的传输方法来解决上述存在的问题。
本发明的目的在于提供一种实现红外数据、温感数据和其他数据的传输方法,以解决上述背景技术中提出的ARM处理器与FPAG进行模式切换控制、档位状态更新、电动或则手动调焦时,无法实时进行接收处理,会出现电视换台的“黑屏”现象的问题。
为实现上述目的,本发明提供如下技术方案:一种实现红外数据、温感数据和其他数据的传输方法,包括处理器机盒和数据信息采集单元,所述处理器机盒的内部安装有控制电路板,控制电路板的内部分别安装有数据打包模块、数据发送模块、数据接收模块、数据解包模块、测温处理模块和图像处理模块,所述数据信息采集单元的输出端与数据打包模块的的输入端之间通过电性连接,数据打包模块的输出端与数据发送模块的输入端之间通过电性连接,数据发送模块的输出端与数据接收模块的输入端之间通过电性连接,数据接收模块的输出端与数据解包模块的输入端之间通过电性连接,数据解包模块的输出端与测温处理模块的输入端之间通过电性连接,测温处理模块的输出端与图像处理模块的输入端之间通过电性连接。
优选的,所述处理器机盒的上端通过控制杆固定连接有显示屏,处理器机盒的前端表面设置有四个通信接口。
优选的,所述处理器机盒的前端表面设置有电源进线孔、数据传输接口、音频输出接口和电源开关。
优选的,所述数据信息采集单元包括红外数据信息、测温档位数据信息、温感数据信息、焦距位置数据信息、镜头信息和挡片位置信息。
优选的,所述FPGA端通过对红外数据和其他数据的重新打包并且调整数据输出的阵列,ARM端接收完一帧数据后解包来完成。
优选的,所述红外数据信息为采集的探测器AD值阵列数据,测温档位数据信息为手动切换或FPGA根据算法实现自动切换,焦距位置数据信息会因为手动调焦或则电动调焦实时改变。
(1)本发明可以在红外测温设备领域整体从技术上提升ARM端处理红外数据和测温计算的实时性,提高了每帧红外数据处理的有效性,降低因为通过IIC或TTL进行主动查询或则被动接收导致的CPU占用率。
(2)数据信息采集单元对红外数据信息、测温档位数据信息、温感数据信息、焦距位置数据信息、镜头信息和挡片位置信息进行采集,通过对数据信息进行打包处理,进行统一整合发送,随后对数据进行接收和解包处理,测温处理模块用于对设备进行实时测温检测,通过图像处理模块进行成像显示,通过ARM处理器与FPAG进行模式切换控制、档位状态更新、电动或则手动调焦时,可以实时进行接收处理,解决了ARM端与FPGA之间的红外数据、温感值、挡片位置、焦距值、测温档位等数据的实时同步传输问题,可提升设备用户操作的交互体验。
图1为本发明的处理器机盒结构示意图。
图2为本发明的控制电路板结构示意图。
图3为本发明的原理框图。
图中:1、显示屏;2、控制杆;3、处理器机盒;4、通信接口;5、电源进线孔;6、数据传输接口;7、音频输出接口;8、电源开关;9、控制电路板;10、数据接收模块;11、数据发送模块;12、数据打包模块;13、图像处理模块;14、数据解包模块;15、测温处理模块;16、数据信息采集单元。
下面将结合本发明实施例中的附图,对本发明实施例中的技术方案进行清楚、完整地描述,显然,所描述的实施例仅仅是本发明一部分实施例,而不是全部的实施例。
请参阅图1-3,本发明提供的一种实施例:一种实现红外数据、温感数据和其他数据的传输方法,包括处理器机盒3和数据信息采集单元16,处理器机盒3的内部安装有控制电路板9,控制电路板9的内部分别安装有数据打包模块12、数据发送模块11、数据接收模块10、数据解包模块14、测温处理模块15和图像处理模块13,数据信息采集单元16的输出端与数据打包模块12的的输入端之间通过电性连接,数据打包模块12的输出端与数据发送模块11的输入端之间通过电性连接,数据发送模块11的输出端与数据接收模块10的输入端之间通过电性连接,数据接收模块10的输出端与数据解包模块14的输入端之间通过电性连接,数据解包模块14的输出端与测温处理模块15的输入端之间通过电性连接,测温处理模块15的输出端与图像处理模块13的输入端之间通过电性连接。
进一步,处理器机盒3的上端通过控制杆2固定连接有显示屏1,处理器机盒3的前端表面设置有四个通信接口4。
进一步,处理器机盒3的前端表面设置有电源进线孔5、数据传输接口6、音频输出接口7和电源开关8。
进一步,数据信息采集单元16包括红外数据信息、测温档位数据信息、温感数据信息、焦距位置数据信息、镜头信息和挡片位置信息。
进一步,FPGA端通过对红外数据和其他数据的重新打包并且调整数据输出的阵列,ARM端接收完一帧数据后解包来完成。
进一步,红外数据信息为采集的探测器AD值阵列数据,测温档位数据信息为手动切换或FPGA根据算法实现自动切换,焦距位置数据信息会因为手动调焦或则电动调焦实时改变。
工作原理:使用时,处理器机盒3的内部安装有控制电路板9,控制电路板9的内部分别安装有数据打包模块12、数据发送模块11、数据接收模块10、数据解包模块14、测温处理模块15和图像处理模块13,数据信息采集单元16包括红外数据信息、测温档位数据信息、温感数据信息、焦距位置数据信息、镜头信息和挡片位置信息,数据信息采集单元16对红外数据信息、测温档位数据信息、温感数据信息、焦距位置数据信息、镜头信息和挡片位置信息进行采集,数据信息采集单元16的输出端与数据打包模块12的的输入端之间通过电性连接,数据打包模块12的输出端与数据发送模块11的输入端之间通过电性连接,数据打包模块12和数据发送模块11通过对数据信息进行打包处理,进行统一整合发送,数据发送模块11的输出端与数据接收模块10的输入端之间通过电性连接,数据接收模块10的输出端与数据解包模块14的输入端之间通过电性连接,数据解包模块14的输出端与测温处理模块15的输入端之间通过电性连接,随后对数据进行接收和解包处理,测温处理模块15用于对设备进行实时测温检测,测温处理模块15的输出端与图像处理模块13的输入端之间通过电性连接,通过图像处理模块13进行成像显示,通过ARM处理器与FPAG进行模式切换控制、档位状态更新、电动或则手动调焦时,可以实时进行接收处理,解决了ARM端与FPGA之间的红外数据、温感值、挡片位置、焦距值、测温档位等数据的实时同步传输问题,可提升设备用户操作的交互体验,本发明可以在红外测温设备领域整体从技术上提升ARM端处理红外数据和测温计算的实时性,提高了每帧红外数据处理的有效性,降低因为通过IIC或TTL进行主动查询或则被动接收导致的CPU占用率。
对于本领域技术人员而言,显然本发明不限于上述示范性实施例的细节,而且在不背离本发明的精神或基本特征的情况下,能够以其他的具体形式实现本发明;因此,无论从哪一点来看,均应将实施例看作是示范性的,而且是非限制性的,本发明的范围由所附权利要求而不是上述说明限定,因此旨在将落在权利要求的等同要件的含义和范围内的所有变化囊括在本发明内。不应将权利要求中的任何附图标记视为限制所涉及的权利要求。
Claims (6)
- 一种实现红外数据、温感数据和其他数据的传输方法,包括处理器机盒(3)和数据信息采集单元(16),其特征在于,所述处理器机盒(3)的内部安装有控制电路板(9),控制电路板(9)的内部分别安装有数据打包模块(12)、数据发送模块(11)、数据接收模块(10)、数据解包模块(14)、测温处理模块(15)和图像处理模块(13),所述数据信息采集单元(16)的输出端与数据打包模块(12)的的输入端之间通过电性连接,数据打包模块(12)的输出端与数据发送模块(11)的输入端之间通过电性连接,数据发送模块(11)的输出端与数据接收模块(10)的输入端之间通过电性连接,数据接收模块(10)的输出端与数据解包模块(14)的输入端之间通过电性连接,数据解包模块(14)的输出端与测温处理模块(15)的输入端之间通过电性连接,测温处理模块(15)的输出端与图像处理模块(13)的输入端之间通过电性连接。
- 根据权利要求1所述的一种实现红外数据、温感数据和其他数据的传输方法,其特征在于:所述处理器机盒(3)的上端通过控制杆(2)固定连接有显示屏(1),处理器机盒(3)的前端表面设置有四个通信接口(4)。
- 根据权利要求1所述的一种实现红外数据、温感数据和其他数据的传输方法,其特征在于:所述处理器机盒(3)的前端表面设置有电源进线孔(5)、数据传输接口(6)、音频输出接口(7)和电源开关(8)。
- 根据权利要求1所述的一种实现红外数据、温感数据和其他数据的传输方法,其特征在于:所述数据信息采集单元(16)包括红外数据信息、测温档位数据信息、温感数据信息、焦距位置数据信息、镜头信息和挡片位置信息。
- 根据权利要求1所述的一种实现红外数据、温感数据和其他数据的传输方法,其特征在于:所述FPGA端通过对红外数据和其他数据的重新打包并且调整数据输出的阵列,ARM端接收完一帧数据后解包来完成。
- 根据权利要求4所述的一种实现红外数据、温感数据和其他数据的传输方法,其特征在于:所述红外数据信息为采集的探测器AD值阵列数据,测温档位数据信息为手动切换或FPGA根据算法实现自动切换,焦距位置数据信息会因为手动调焦或则电动调焦实时改变。
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