欢迎访问ic37.com |
会员登录 免费注册
发布采购

5M80ZT100C5 参数 Datasheet PDF下载

5M80ZT100C5图片预览
型号: 5M80ZT100C5
PDF下载: 下载PDF文件 查看货源
内容描述: [Flash PLD, 14ns, PQFP100, 16 X 16 MM, 0.50 MM PITCH, TQFP-100]
分类和应用: 时钟可编程逻辑
文件页数/大小: 166 页 / 4004 K
品牌: ALTERA [ ALTERA CORPORATION ]
 浏览型号5M80ZT100C5的Datasheet PDF文件第96页浏览型号5M80ZT100C5的Datasheet PDF文件第97页浏览型号5M80ZT100C5的Datasheet PDF文件第98页浏览型号5M80ZT100C5的Datasheet PDF文件第99页浏览型号5M80ZT100C5的Datasheet PDF文件第101页浏览型号5M80ZT100C5的Datasheet PDF文件第102页浏览型号5M80ZT100C5的Datasheet PDF文件第103页浏览型号5M80ZT100C5的Datasheet PDF文件第104页  
6–6  
Chapter 6: JTAG and In-System Programmability in MAX V Devices  
In-System Programmability  
IEEE 1532 Support  
The JTAG circuitry and ISP instruction set in MAX V devices are compliant to the  
IEEE-1532-2002 programming specification. This provides industry-standard  
hardware and software for in-system programming among multiple vendor  
programmable logic devices (PLDs) in a JTAG chain.  
f For more information about MAX V 1532 Boundary-Scan Description Language  
(.bsd) files, refer to the IEEE 1532 BSDL Files page of the Altera website.  
Jam Standard Test and Programming Language  
You can use the Jam STAPL to program MAX V devices with in-circuit testers, PCs, or  
embedded processors. The Jam byte code is also supported for MAX V devices. These  
software programming protocols provide a compact embedded solution for  
programming MAX V devices.  
f For more information, refer to AN 425: Using Command-Line Jam STAPL Solution for  
Device Programming.  
Programming Sequence  
During in-system programming, 1532 instructions, addresses, and data are shifted  
into the MAX V device through the TDIinput pin. Data is shifted out through the TDO  
output pin and compared with the expected data.  
To program a pattern into the device, follow these steps:  
1. Enter ISP—The enter ISP stage ensures that the I/O pins transition smoothly from  
user mode to ISP mode.  
2. Check ID—The silicon ID is checked before any Program or Verify process. The  
time required to read this silicon ID is relatively small compared to the overall  
programming time.  
3. Sector Erase—Erasing the device in-system involves shifting in the instruction to  
erase the device and applying an erase pulse or pulses. The erase pulse is  
automatically generated internally by waiting in the run, test, or idle state for the  
specified erase pulse time of 500 ms for the CFM block and 500 ms for each sector  
of the user flash memory (UFM) block.  
4. Program—Programming the device in-system involves shifting in the address,  
data, and program instruction and generating the program pulse to program the  
flash cells. The program pulse is automatically generated internally by waiting in  
the run/test/idle state for the specified program pulse time of 75 µs. This process  
is repeated for each address in the CFM and UFM blocks.  
5. VerifyVerifying a MAX V device in-system involves shifting in addresses,  
applying the verify instruction to generate the read pulse, and shifting out the data  
for comparison. This process is repeated for each CFM and UFM address.  
6. Exit ISP—An exit ISP stage ensures that the I/O pins transition smoothly from ISP  
mode to user mode.  
MAX V Device Handbook  
May 2011 Altera Corporation  
 复制成功!