In the early days, embedded systems were built primarily by engineers in a pretty exclusive club. Embedded devices and software tools were expensive, and building a functional prototype required significant software engineering and electrical engineering experience.
標簽: Arduino Gadgets Make Bots and
上傳時間: 2020-06-09
上傳用戶:shancjb
1. Scope ......................................................................................................................................................................... 12. DDR4 SDRAM Package Pinout and Addressing ....................................................................................................... 22.1 DDR4 SDRAM Row for X4,X8 and X16 ................................................................................................................22.2 DDR4 SDRAM Ball Pitch........................................................................................................................................22.3 DDR4 SDRAM Columns for X4,X8 and X16 ..........................................................................................................22.4 DDR4 SDRAM X4/8 Ballout using MO-207......................................................................................................... 22.5 DDR4 SDRAM X16 Ballout using MO-207.............................................................................................................32.6 Pinout Description ..................................................................................................................................................52.7 DDR4 SDRAM Addressing.....................................................................................................................................73. Functional Description ...............................................................................................................................................83.1 Simplified State Diagram ....................................................................................................................................83.2 Basic Functionality..................................................................................................................................................93.3 RESET and Initialization Procedure .....................................................................................................................103.3.1 Power-up Initialization Sequence .............................................................................................................103.3.2 Reset Initialization with Stable Power ......................................................................................................113.4 Register Definition ................................................................................................................................................123.4.1 Programming the mode registers .............................................................................................................123.5 Mode Register ......................................................................................................................................................134. DDR4 SDRAM Command Description and Operation ............................................................................................. 244.1 Command Truth Table ..........................................................................................................................................244.2 CKE Truth Table ...................................................................................................................................................254.3 Burst Length, Type and Order ..............................................................................................................................264.3.1 BL8 Burst order with CRC Enabled .........................................................................................................264.4 DLL-off Mode & DLL on/off Switching procedure ................................................................................................274.4.1 DLL on/off switching procedure ...............................................................................................................274.4.2 DLL “on” to DLL “off” Procedure ..............................................................................................................274.4.3 DLL “off” to DLL “on” Procedure ..............................................................................................................284.5 DLL-off Mode........................................................................................................................................................294.6 Input Clock Frequency Change ............................................................................................................................304.7 Write Leveling.......................................................................................................................................................314.7.1 DRAM setting for write leveling & DRAM termination function in that mode ............................................324.7.2 Procedure Description .............................................................................................................................334.7.3 Write Leveling Mode Exit .........................................................................................................................34
標簽: DDR4
上傳時間: 2022-01-09
上傳用戶:
PW4203 is a 4.5-22V input, 2A multi-cell synchronous Buck Li-Ion battery charger, suitable forportable application. Select pin is convenient for multi-cell charging. 800 kHz synchronous buckregulator integrates of 22V rating FETs with ultra low on- resistance to achieve high efficiency andsimple circuit design.The PW4203 is available in an 8-pin SOP package, provides a very compact system solution andgood thermal conductance
標簽: pw4203
上傳時間: 2022-02-11
上傳用戶:
基于藥物治療在臨床治療中的重要性,分析目前服藥提醒裝置存在的不足,以STM32F103VET6單片機為控制核心,設計了一種多功能電子藥箱。該系統包括顯示模塊、語音模塊和數據存儲模塊。顯示模塊通過觸摸屏電路和LED指示燈電路,與語音模塊相配合,實現了服藥提醒及指導的功能;數據存儲模塊通過EEPROM存儲電路,能夠實現掉電時服藥信息不丟失的功能。并且為了實現電子藥箱的智能化控制,開發了手機APP,兩者之間可通過WIFI進行數據通信。經測試,該藥箱能夠有效地幫助慢性病患者按時、定量、正確服用藥物,適合在家庭中推廣使用,具有較高的應用價值和實踐意義。Based on the importance of drug therapy in clinical treatment, this paper analyzes the shortcomings of current drug reminder devices, and designs a multi-function electronic medicine box with STM32 F103 VET6 microcontroller as the control core. The system includes a display module, a voice module, and a data storage module. The display module cooperates with the voice module through the touch screen circuit and the LED indicator circuit to realize the function of reminding and guiding the medicine;the data storage module can realize the function of not losing the medication information when the power is off through the EEPROM storage circuit.After testing, the medicine box can effectively help chronic diseases patients to take drugs on time, in a quantitative and correct manner,and is suitable for popularization in the family, and has high application value and practical significance.
標簽: 電子藥箱
上傳時間: 2022-03-27
上傳用戶:
目的:自主研制一款超聲手術刀電源控制系統,以減少能量的消耗,維持手術刀的正常溫度。方法:對超聲換能器在諧振附近的等效電路建立模型,并設計基于數字信號處理(DSP)的超聲手術刀的硬件控制系統。結果:經對電源控制系統的電路和工作性能測試,生成的電流和電壓的有效值等參數,能夠及時調整電源的頻率,并達到預期的功能指標,使超聲手術刀工作在諧振狀態。結論:以DSP為核心設計的超聲手術刀電源控制系統,測試指標均能夠達到預期的要求,能夠使系統在諧振狀態下工作。Objective: To independently develop a power control system of ultrasonic scalpel so as to reduce the energy consumption and maintain the normal temperature of ultrasonic scalpel. Methods: In this paper, the model of equivalent circuit of ultrasonic transducer nearby syntony was built up, and the hardware control system of ultrasonic scalpel based on digital signal processing(DSP) was designed. Results: Through testing the circuit and work performance of power control system, the series of parameters such as effective value and so on which were produced by this system could adjust frequency of power source in time and attain anticipative functional indicator, and it took the ultrasonic scalpel to work in syntonic situation. Conclusion: The tested indicators of power control system of ultrasonic scalpel based on the kernel design of DSP can attain anticipative requirement, and can take this system to work in syntonic situation.
上傳時間: 2022-04-03
上傳用戶:bluedrops
說明: 51單片機控制智能溫控風扇,多檔調節,pwd調速。包含源碼和電路圖(51 single chip computer control intelligent temperature control fan, multi-stage adjustment, PWD speed regulation. Contains source code and circuit diagrams)
上傳時間: 2022-05-17
上傳用戶:
ISO 26262《道路車輛功能安全》國際標準是針對總重不超過3.5噸八座乘用車,以安全相關電子電氣系統的特點所制定的功能安全標準,基于IEC 61508《安全相關電氣/電子/可編程電子系統功能安全》制定,在2011年11月15日正式發布。ISO 26262是史上第一個適用于大批量量產產品的功能安全(Functional Safety)標準。特別需要注意的是,ISO 26262僅針對安全相關電子電氣系統,包含電機、電子與軟件零件,不應用于非電子電氣系統(如機械、液壓等)。功能安全之設計議題在汽車領域已被重視,因其關系人員安全與公司商譽等問題,透過危害分析與風險評估(Hazard Analysis & Risk Assessment,HARA)及V模型設計架構,使功能安全需求等級得到一致性的分析結果,以利汽車電子系統之生命周期考慮到所需失效防止技術與管理要求,并借由設計開發、查證(Verification)及確認(Validation)等能力成熟度模型集成(CMMI-DEV)流程加以實現,使得產品之功能安全符合所需汽車安全完整性等級(ASIL)。
上傳時間: 2022-05-30
上傳用戶:
ISO 26262《道路車輛功能安全》國際標準是針對總重不超過3.5噸八座乘用車,以安全相關電子電氣系統的特點所制定的功能安全標準,基于IEC 61508《安全相關電氣/電子/可編程電子系統功能安全》制定,在2011年11月15日正式發布。ISO 26262是史上第一個適用于大批量量產產品的功能安全(Functional Safety)標準。特別需要注意的是,ISO 26262僅針對安全相關電子電氣系統,包含電機、電子與軟件零件,不應用于非電子電氣系統(如機械、液壓等)。功能安全之設計議題在汽車領域已被重視,因其關系人員安全與公司商譽等問題,透過危害分析與風險評估(Hazard Analysis & Risk Assessment,HARA)及V模型設計架構,使功能安全需求等級得到一致性的分析結果,以利汽車電子系統之生命周期考慮到所需失效防止技術與管理要求,并借由設計開發、查證(Verification)及確認(Validation)等能力成熟度模型集成(CMMI-DEV)流程加以實現,使得產品之功能安全符合所需汽車安全完整性等級(ASIL)。
上傳時間: 2022-05-30
上傳用戶:
ISO 26262《道路車輛功能安全》國際標準是針對總重不超過3.5噸八座乘用車,以安全相關電子電氣系統的特點所制定的功能安全標準,基于IEC 61508《安全相關電氣/電子/可編程電子系統功能安全》制定,在2011年11月15日正式發布。ISO 26262是史上第一個適用于大批量量產產品的功能安全(Functional Safety)標準。特別需要注意的是,ISO 26262僅針對安全相關電子電氣系統,包含電機、電子與軟件零件,不應用于非電子電氣系統(如機械、液壓等)。功能安全之設計議題在汽車領域已被重視,因其關系人員安全與公司商譽等問題,透過危害分析與風險評估(Hazard Analysis & Risk Assessment,HARA)及V模型設計架構,使功能安全需求等級得到一致性的分析結果,以利汽車電子系統之生命周期考慮到所需失效防止技術與管理要求,并借由設計開發、查證(Verification)及確認(Validation)等能力成熟度模型集成(CMMI-DEV)流程加以實現,使得產品之功能安全符合所需汽車安全完整性等級(ASIL)。
上傳時間: 2022-05-30
上傳用戶:得之我幸78
ISO 26262《道路車輛功能安全》國際標準是針對總重不超過3.5噸八座乘用車,以安全相關電子電氣系統的特點所制定的功能安全標準,基于IEC 61508《安全相關電氣/電子/可編程電子系統功能安全》制定,在2011年11月15日正式發布。ISO 26262是史上第一個適用于大批量量產產品的功能安全(Functional Safety)標準。特別需要注意的是,ISO 26262僅針對安全相關電子電氣系統,包含電機、電子與軟件零件,不應用于非電子電氣系統(如機械、液壓等)。功能安全之設計議題在汽車領域已被重視,因其關系人員安全與公司商譽等問題,透過危害分析與風險評估(Hazard Analysis & Risk Assessment,HARA)及V模型設計架構,使功能安全需求等級得到一致性的分析結果,以利汽車電子系統之生命周期考慮到所需失效防止技術與管理要求,并借由設計開發、查證(Verification)及確認(Validation)等能力成熟度模型集成(CMMI-DEV)流程加以實現,使得產品之功能安全符合所需汽車安全完整性等級(ASIL)。
上傳時間: 2022-05-30
上傳用戶:
