为设计高效率、低损耗的PFC电路,本文基于UCC28019进行电路设计。以UCC28019输出的PWM波形来控制Boost升压斩波为核心电路,使电路中的电容交替地充放电、电感交替的储存和释放能量,最后实现在输入AC20V~24V电压情况下稳定输出DC38V。测试结果表明,系统实现效率为95%左右,电压调整率小于1%,电源功率因数0.99。交流输入电压为19.0-25.8 V时,输出直流电压稳定性较好,电感无明显啸叫且纹波小,具有一定的带负载能力和实用性。In order to design the PFC circuit with high efficiency and low loss,this paper designs the circuit based on UCC28019.The PWM waveform output by UCC28019 is used to control boost chopper as the CORE circuit,which alternately charges and discharges capacitors,stores and releases energy by inductors,and finally achieves stable output of DC38 V under the input voltage of AC20 V~24 V.The test results show that the system achieves about 95% efficiency,the voltage adjustment rate is less than 1%,the power factor is 0.99,and the AC input voltage is 19.0-25.8 V.The output DC voltage stability is good,the inductance has no obvious whistle and the ripple is small,so it has certain load capacity and practicability.
上传时间: 2022-04-03
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1. Preface2. The concept2.2. Prescience 2.3. Reading guide 2.4. Abbreviations 2.5. Version management3. Hardware3.2. ESP32 3.3.2. Hardware schema 3.3.3. DHT22 and level shifter 3.3.4. Geekcreit® ESP32 Development Board4. Software4.2. Installatie van GIT 4.3. Installatation of the ESP32 CORE 4.4. Installation of the Xtensa and ESP32 Tools 4.5. Python 4.5.1. Install Python 4.5.2. Installation of pySerial and EspTool 4.6. Test the software installation5. The ESP32 IoT project 5.1.1. WiFi connection 5.1.2. Setup date and time 5.1.3. MQTT connection 5.1.4. Determining temperature and humidity 5.2. IOT_ESP32_Project source6. Test6.2. ESP32, NodeJS, MongoDB en Mosca 6.2.1. Start MongoDB 6.2.2. Start NodeJS Express serve and Mosca broker 6.2.3. Start the ESP32 6.2.4. Start an Chrome browser
上传时间: 2022-04-05
上传用户:kingwide
高通(Qualcomm)蓝牙芯片QCC5144_硬件设计详细指导书(官方内部培训手册)其内容是针对硬件设计、部分重要元器件选择(ESD,Filter)及走线注意事项的详细说明。2 Power management 2.1 SMPS 2.1.1 Components specification 2.1.2 Input power supply selection 92.1.3 Minimize SMPS EMI emissions 2.1.4 Internal LDOs and digital CORE decoupling 2.1.5 Powering external components 2.2 Charger 2.2.1 Charger connections.2.2.2 General charger operation2.2.3 Temperature measurement during charging 2.3 SYS_CTRL 3 Bluetooth radio3.1 RF PSU component choice 3.2 RF band-pass filter3.3 Layout (天线 走线的注意事项)4 Audio4.1 Audio bypass capacitors 4.2 Earphone speaker output4.3 Line/Mic input 4.4 Headphone output optimizition5 LED pads 5.1 LED driver 5.2 Digital/Button input 5.3 Analog input5.4 Disabled 6 Reset pin (Reset#)7 USB interfaces7.1 USB device port7.1.1 USB device port7.1.2 Layout notes 7.1.3 USB charger detectionA QCC5144 VFBGA example schematic and BOM B Recommended SMPS components specificationB.1 Inductor specifition B.2 Recommended inductors B.3 SMPS capacitor specifition
上传时间: 2022-04-07
上传用户:默默
STM32 F0系列 MCU 集成库 原理图库 PCB封装库文件CSV text has been written to file : STM32 F0.csvLibrary Component Count : 17Name Description----------------------------------------------------------------------------------------------------STM32F050C4T6A ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 16kB Flash, 4 kB Internal RAM, 39 High Current I/Os, -40 to +85癈, 48-Pin LQFP, TraySTM32F050C6T6 ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 32kB Flash, 4 kB Internal RAM, 39 High Current I/Os, -40 to +85癈, 48-Pin LQFP, TraySTM32F050C6T6A ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 32kB Flash, 4 kB Internal RAM, 39 High Current I/Os, -40 to +85癈, 48-Pin LQFP, TraySTM32F050K4U6A ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 16kB Flash, 4 kB Internal RAM, 27 High Current I/Os, -40 to +85癈, 32-Pin UFQFPN, TraySTM32F050K6U6A ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 32kB Flash, 4 kB Internal RAM, 27 High Current I/Os, -40 to +85癈, 32-Pin UFQFPN, TraySTM32F051C4T6 ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 16kB Flash, 4 kB Internal RAM, 39 High Current I/Os, -40 to +85癈, 48-Pin LQFP, TraySTM32F051C6T6 ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 32kB Flash, 4 kB Internal RAM, 39 High Current I/Os, -40 to +85癈, 48-Pin LQFP, TraySTM32F051C8T6 ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 64kB Flash, 8 kB Internal RAM, 39 High Current I/Os, -40 to +85癈, 48-Pin LQFP, TraySTM32F051K4U6 ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 16kB Flash, 4 kB Internal RAM, 27 High Current I/Os, -40 to +85癈, 32-Pin UFQFPN, TraySTM32F051K6U6 ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 32kB Flash, 4 kB Internal RAM, 27 High Current I/Os, -40 to +85癈, 32-Pin UFQFPN, TraySTM32F051K8U6 ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 64kB Flash, 8 kB Internal RAM, 27 High Current I/Os, -40 to +85癈, 32-Pin UFQFPN, TraySTM32F051R4T6 ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 16kB Flash, 4 kB Internal RAM, 55 High Current I/Os, -40 to +85癈, 64-Pin LQFP, TraySTM32F051R4T6TR ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 16kB Flash, 4 kB Internal RAM, 55 High Current I/Os, -40 to +85癈, 64-Pin LQFP, Tape and ReelSTM32F051R6T6 ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 32kB Flash, 4 kB Internal RAM, 55 High Current I/Os, -40 to +85癈, 64-Pin LQFP, TraySTM32F051R8T6 ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 64kB Flash, 8 kB Internal RAM, 55 High Current I/Os, -40 to +85癈, 64-Pin LQFP, TraySTM32F051R8T7 ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 64kB Flash, 8 kB Internal RAM, 55 High Current I/Os, -40 to +105癈, 64-Pin LQFP, TraySTM32F051R8TR ARM Cortex-M0 32-bit RISC CORE (48 MHz max), 64kB Flash, 8 kB Internal RAM, 55 High Current I/Os, -40 to +105癈, 64-Pin LQFP, Tape and Reel
上传时间: 2022-04-30
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基于TMS320F28335的超声波流量计硬件原理图+软件源码本文以TMS320F28335 处理器为核心,设计一种用于管道流量测量的超声波流量计。系统硬件由核心板,超声波发射和接收电路,切换电路,超声换能器,基于ADS805 的高速信号采集电路,人机交互以及电源等模块构成。采用时差法进行管道流量测量,时差测量采用SCOT 加权的广义互相关时延估计算法。本论文设计的超声波流量计具有测量速度快、准确性好、成本低等优点。关键字:C2000,超声波,流量,广义互相关算法AbstractA kind of ultrasonic flowmeter using for the pipe flow measurement is designed based onTMS320F28335 in this paper. The system hardware consists of the following parts: the CORE board,ultrasonic signal transmitter and receiver circuits, switch circuit, ultrasonic transducer, signalacquisition circuit based on ADS805, human-computer interaction module and power supplymodule, etc. The system use the method of time difference for pipeline flow measurement and thetime difference is calculated by the time-delay algorithm of SCOT weighted generalizedcross-correlation. The ultrasonic flowmeter has the features of high testing speed, high precisionand low cost, etc.Keywords: C2000,Ultrasonic, Flow, Generalized Cross-Correlation Algorithm
标签: tms320f28335 超声波流量计
上传时间: 2022-05-06
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以STM32F103C8T6为核心,设计了无刷直流电机控制器硬件电路。电路主要包括IR2310构成的PWM驱动电路、IRF3808构成的逆变电路、增量式旋转编码构成的速度反馈电路。控制器具有CAN和RS232通信接口,可与计算机或PLC构成速度或位置伺服系统。利用由xPC目标搭建的半实物仿真平台对PI参数进行整定。测试了控制器的速度伺服响应性能,给定速度为2400rpm时,控制器响应时间为0.32s。实验结果表明,系统工作可靠,稳定性好,响应速度快,可以满足上肢康复机器人的机械臂速度控制性能要求。The hardware circuit of Brushless DC motor controller is designed by taking STM32F103C8T6 as the CORE,which mainly includes PWM driving circuits made up of IR2310,inverter circuit formed by IRF3808,speed feedback circuit composed of incremental rotary encoder and so on.Speed servo control system or position servo control system can be composed of BLDM controller with computer or PLC through CAN communication interface or RS232 serial communication interface.By using the hardware in the loop simulation platform built by xPC target,the PI parameters are set up.The Speed servo response performance of the controller is tested.When the speed is 2 400 rpm,the response time of the controller is 0...
上传时间: 2022-05-07
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基于DSP28035的高速永磁无刷直流电机驱动系统,包括论文和软硬设计资料。摘要参赛作品为基于DSP28035的高速永磁无刷直流电机驱动系统。该系统以一台额定转速60 krpm的高速永磁无刷直流电机、交错并联的Buck电路以及全桥电路为硬件平台,以DSP28035为控制核心,实现了调压调速功能和基于坐标变换的无位置传感器新技术。为实现该系统要求,本作品充分利用了DSP28035的资源例如:CLA模块,模拟比较器、HPWM模块以及AD转换模块等。AbstractThis work is the drive system for a high speed permanent magnet burshless dc motor based on DSP28035. The hardware platform consists of a BLDC motor(rated speed is 60000rpm), a Buck circuit and an inverter. Under the control of DSP28035, this system can achieve the goal of adjusting the motor’s speed with voltage and the function of sensorless control based on the coordinate transformation. By making full use of resources of the CORE, such as CLA, analog comparator, HPWM and AD converters, the whole system can meet the requirements.1 引言高速永磁无刷直流电机驱动系统由于基波频率较高(一般在1kHZ以上),利用逆变桥斩波进行调速的控制方式通常会受到开关管开关频率的限制,因此该系统多采用三相全桥前级加Buck电路进承担调压调速的功能,而三相全桥主要承担逻辑换相的功能。然而,传统Buck电路所需电感的体积较大,增加了系统的体积,降低了系统的功率密度。
上传时间: 2022-05-08
上传用户:bluedrops
Artix-7 XC7A35T-DDR3开发板资料硬件参考设计资料QM_ XC7A35T开发板主要特征参数如下所示: 主控FPGA:XC7A35T-1FTG256C; 主控FPGA外部时钟源频率:50MHz; XC7A35T-1FTG256C芯片内部自带丰富的Block RAM资源,达到了1,800kb; XC7A35T-1FTG256C芯片逻辑单元数为33,280; QM _XC7A35T板载N25Q064A SPI Flash芯片,8MB(64Mbit)的存储容量; QM _XC7A35T板载256MB镁光的DDR3存储器,型号为MT41K128M16JT-125:K; QM _XC7A35T提供核心板芯片工作的3.3V电源,有一路3.3V的LED电源指示灯,板载高性能DC/DC芯片给FPGA 1.0V CORE电压,DDR3 1.5V电压供电以及VDD_AUX的1.8V电压; QM _XC7A35T引出了两排2x32p、2.54mm间距的排座,可以用于外接24Bit的TFT液晶屏、CY7C68013 USB模块、高速ADC采集模块或者CMOS摄像头模块等; QM _XC7A35T引出了芯片的2路按键用于测试,其中一路用于PROGROM_B信号编程按钮; QM _XC7A35T引出了芯片的3路LED灯用于测试,其中一路LED为FPGA_DONE信号指示灯; QM _XC7A35T引出了芯片的JTAG调试端口,采用单排6p、2.54mm间距的排针;
标签: DDR3
上传时间: 2022-05-11
上传用户:shjgzh
脉冲的Y770的使用资料,针对硬件手册、软件手册、屏幕规格书的内容
标签: MC-A33-CORE
上传时间: 2022-05-31
上传用户:canderile
随着通信、网络、计算机技术的发展给传统控制技术的发展带来了新的契机。蓝牙技术是一种用于各种固定与移动的数字化硬件设备之间的一种低成本、高效率的无线通信连接技术,在实际应用中取代了烦琐的电缆连接。本课题以英国Cambridge SiliconRadio公司生的BlueCORE"M02蓝牙芯片作为研究对象,以蓝牙1.2协议栈为设计指导,给出了基于蓝牙HID协议栈的串口键盘鼠标取数据采集实现方案。蓝牙规范是亩蓝牙SIG开发的免费开放的蓝牙技术标准,包括核心规范(CORE Specification)和应用规范(Profile)两个部分。核心规范定义了各层协议各自的工作方式,而应用规范是为了实现一个特定的应用模型而采取的特定协议层间的运行机制。整个蓝牙协议体系可分为底层硬件模块、中间协议层和高端应用层三部分。链路管理层、基带层和射频层属于蓝牙硬件模块。逻辑链路控制和适配协议、服务发现协议、串口仿真协议属于中间协议层,一般用软件实现。高端应用层是对用于各种应用模型的Profile.本论文首先分析和研究了蓝牙核心协议,然后重点分析了基于蓝牙HID高端应用模式的实现,用软件实现了基于HID协议的HC1、逻辑链路控制适配协议和服务发现协议。然后在HID应用规范的基础上给出了以串口方式实现键盘和鼠标数据采集的硬件和软件设计,整个系统设计结合蓝牙开发工具BBDK,给出了基于HID规范实现键盘鼠标的完整设计过程。在扫描码采集端以微处理器方式做为蓝牙主机实现HID高层应用规范,蓝牙主机内用C语言实现基于HID协议HCI,L2CAP,SDP:在PC机端用PC机做为蓝牙主机,在VC++6.0环境下用C++的类封装方式实现上述协议。
上传时间: 2022-05-31
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