This is the second half of our Transistor Circuits e-book. It contains a further 100 circuits, with many of them containing one or more Integrated Circuits (ICs).It's amazing what you can do with transistors but when Integrated Circuits came along, the whole field of electronics exploded.
上傳時間: 2013-11-08
上傳用戶:603100257
大綱1 公司簡介2 LAY OUT圖3 設備清單4 設備規格5 維護6 貿易條件7 建議
上傳時間: 2013-10-19
上傳用戶:wawjj
ANDB (字節與) 指令對兩個輸入字節按位與 得到一個字節結果 (OUT)ORB (字節或) 指令對兩個輸入字節按位或 得到一個字節結果 (OUT)XORB (字節異或) 指令對兩個輸入字節按位異或得到一個字節結果 (OUT)使 ENO = 0 的錯誤條件是SM4.3 (運行時間) 0006 (間接尋址)這些指令影響下面的特殊存儲器位 SM1.0 (零)
上傳時間: 2013-11-02
上傳用戶:aa54
library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.STD_LOGIC_ARITH.ALL; use IEEE.STD_LOGIC_UNSIGNED.ALL; ---- Uncomment the following library declaration if instantiating ---- any Xilinx primitives in this code. --library UNISIM; --use UNISIM.VComponents.all; entity counter is Port ( clk : in std_logic; resetn : in std_logic; dout : out std_logic_vector(7 downto 0); lcd_en : out std_logic; lcd_rs : out std_logic; lcd_rw : out std_logic); end counter;
上傳時間: 2013-10-30
上傳用戶:wqxstar
This example provides a description of how to use the USART with hardware flowcontrol and communicate with the Hyperterminal.First, the USART2 sends the TxBuffer to the hyperterminal and still waiting fora string from the hyperterminal that you must enter which must end by '\r'character (keypad ENTER button). Each byte received is retransmitted to theHyperterminal. The string that you have entered is stored in the RxBuffer array. The receivebuffer have a RxBufferSize bytes as maximum. The USART2 is configured as follow: - BaudRate = 115200 baud - Word Length = 8 Bits - One Stop Bit - No parity - Hardware flow control enabled (RTS and CTS signals) - Receive and transmit enabled - USART Clock disabled - USART CPOL: Clock is active low - USART CPHA: Data is captured on the second edge - USART LastBit: The clock pulse of the last data bit is not output to the SCLK pin
上傳時間: 2013-10-31
上傳用戶:yy_cn
IBIS 模型在做類似板級SI 仿真得到廣泛應用。在做仿真的初級階段,經常對于ibis 模型的描述有些疑問,只知道把模型拿來轉換為軟件所支持的格式或者直接使用,而對于IBIS 模型里面的數據描述什么都不算很明白,因此下面的一些描述是整理出來的一點對于ibis 的基本理解。在此引用很多presention來描述ibis 內容(有的照抄過來,阿彌陀佛,不要說抄襲,只不過習慣信手拈來說明一些問題),僅此向如muranyi 等ibis 先驅者致敬。本文難免有些錯誤或者考慮不周,隨時歡迎進行討論并對其進行修改!IBIS 模型的一些基本概念IBIS 這個詞是Input/Output buffer information specification 的縮寫。本文是基于IBIS ver3.2 所撰寫出來(www.eigroup.org/IBIS/可下載到各種版本spec),ver4.2增加很多新特性,由于在目前設計中沒用到不予以討論。。。在業界經常會把spice 模型描述為transistor model 是因為它描述很多電路細節問題。而把ibis 模型描述為behavioral model 是因為它并不象spice 模型那樣描述電路的構成,IBIS 模型描述的只不過是電路的一種外在表現,象個黑匣子一樣,輸入什么然后就得到輸出結果,而不需要了解里面驅動或者接收的電路構成。因此有所謂的garbage in, garbage out,ibis 模型的仿真精度依賴于模型的準確度以及考慮的worse case,因此無論你的模型如何精確而考慮的worse case 不周全或者你考慮的worse case 如何周全而模型不精確,都是得不到較好的仿真精度。
上傳時間: 2013-10-16
上傳用戶:zhouli
溫濕度傳感器 sht11 仿真程序 sbit out =P3^0; //加熱口 //sbit input =P1^1;//檢測口 //sbit speek =P2^0;//報警 sbit clo =P3^7;//時鐘 sbit ST =P3^5;//開始 sbit EOC =P3^6;//成功信號 sbit gwei =P3^4;//個位 sbit swei =P3^3;//十位 sbit bwei =P3^2;//百位 sbit qwei =P3^1;//千位 sbit speak =P0^0;//報警音 sbit bjled =P0^1;//報警燈 sbit zcled =P0^2;//正常LED int count; uchar xianzhi;//取轉換結果 uchar seth;//高時間 uchar setl;//低時間 uchar seth_mi;//高時間 uchar setl_mi;//低時間 bit hlbz;//高低標志 bit clbz; bit spbz; ///定時中斷程序/// void t0 (void) interrupt 1 using 0 { TH0=(65536-200)/256;//5ms*200=1000ms=1s TL0=(65536-200)%256; clo=!clo;//產生時鐘 if(count>5000) { if(hlbz) { if(seth_mi==0){seth_mi=seth;hlbz=0;out=0;} else seth_mi--; } if(!hlbz) { if(setl_mi==0){setl_mi=setl;hlbz=1;out=1;} else setl_mi--; } count=0; } else count++; } ///////////// ///////延時/////// delay(int i) { while(--i); } ///////顯示處理/////// xianshi() { int abcd=0; int i; for (i=0;i<5;i++) { abcd=xianzhi; gwei=1; swei=1; bwei=1; qwei=1; P1=dispcode[abcd/1000]; qwei=0; delay(70); qwei=1; abcd=abcd%1000; P1=dispcode[abcd/100]; bwei=0; delay(70); bwei=1; abcd=abcd%100; P1=dispcode[abcd/10]; swei=0; delay(70); swei=1; abcd=abcd%10; P1=dispcode[abcd]; gwei=0; delay(70); gwei=1; } } doing() { if(xianzhi>100) {bjled=0;speak=1;zcled=1;} else {bjled=1;speak=0;zcled=0;} } void main(void) { seth=60;//h60秒 setl=90;//l90秒 seth_mi=60;//h60秒 setl_mi=90;//l90秒 TMOD=0X01;//定時0 16位工作模式 TH0=(65536-200)/256; TL0=(65536-200)%256; TR0=1; //開始計時 ET0=1; //開定時0中斷 EA=1; //開全中斷 while(1) { ST=0; _nop_(); ST=1; _nop_(); ST=0; // EOC=0; xianshi(); while(!EOC) { xianshi(); } xianzhi=P2; xianshi(); doing(); } }
上傳時間: 2013-11-07
上傳用戶:我們的船長
中文版詳情瀏覽:http://www.elecfans.com/emb/fpga/20130715324029.html Xilinx UltraScale:The Next-Generation Architecture for Your Next-Generation Architecture The Xilinx® UltraScale™ architecture delivers unprecedented levels of integration and capability with ASIC-class system- level performance for the most demanding applications. The UltraScale architecture is the industr y's f irst application of leading-edge ASIC architectural enhancements in an All Programmable architecture that scales from 20 nm planar through 16 nm FinFET technologies and beyond, in addition to scaling from monolithic through 3D ICs. Through analytical co-optimization with the X ilinx V ivado® Design Suite, the UltraScale architecture provides massive routing capacity while intelligently resolving typical bottlenecks in ways never before possible. This design synergy achieves greater than 90% utilization with no performance degradation. Some of the UltraScale architecture breakthroughs include: • Strategic placement (virtually anywhere on the die) of ASIC-like system clocks, reducing clock skew by up to 50% • Latency-producing pipelining is virtually unnecessary in systems with massively parallel bus architecture, increasing system speed and capability • Potential timing-closure problems and interconnect bottlenecks are eliminated, even in systems requiring 90% or more resource utilization • 3D IC integration makes it possible to build larger devices one process generation ahead of the current industr y standard • Greatly increased system performance, including multi-gigabit serial transceivers, I/O, and memor y bandwidth is available within even smaller system power budgets • Greatly enhanced DSP and packet handling The Xilinx UltraScale architecture opens up whole new dimensions for designers of ultra-high-capacity solutions.
標簽: UltraScale Xilinx 架構
上傳時間: 2013-11-21
上傳用戶:wxqman
Design techniques for electronic systems areconstantly changing. In industries at the heart of thedigital revolution, this change is especially acute.Functional integration, dramatic increases incomplexity, new standards and protocols, costconstraints, and increased time-to-market pressureshave bolstered both the design challenges and theopportunities to develop modern electronic systems.One trend driving these changes is the increasedintegration of core logic with previously discretefunctions to achieve higher performance and morecompact board designs.
上傳時間: 2013-11-23
上傳用戶:kangqiaoyibie
The standard that governs the design of avioniccomponents and systems, DO-254, is one of the mostpoorly understood but widely applicable standardsin the avionic industry. While information on thegeneral aspects of the standard is easy to obtain, thedetails of exactly how to implement the standard aresketchy. And once an entity develops a process thatachieves compliance, the details of how compliancewas achieved become part of the intellectualproperty of that entity. This white paper focuses onthe details of developing a DO-254 compliantprocess for the design of FPGAs.
上傳時間: 2013-11-03
上傳用戶:ysystc670
