performance.vwf

来自「用verilog编写的程序,用来计算误码率的,可以在编码和解码过程中用的到的!」· VWF 代码 · 共 450 行

VWF
450
字号 
/*
WARNING: Do NOT edit the input and output ports in this file in a text
editor if you plan to continue editing the block that represents it in
the Block Editor! File corruption is VERY likely to occur.
*/

/*
Copyright (C) 1991-2005 Altera Corporation
Your use of Altera Corporation's design tools, logic functions 
and other software and tools, and its AMPP partner logic 
functions, and any output files any of the foregoing 
(including device programming or simulation files), and any 
associated documentation or information are expressly subject 
to the terms and conditions of the Altera Program License 
Subscription Agreement, Altera MegaCore Function License 
Agreement, or other applicable license agreement, including, 
without limitation, that your use is for the sole purpose of 
programming logic devices manufactured by Altera and sold by 
Altera or its authorized distributors.  Please refer to the 
applicable agreement for further details.
*/

HEADER
{
	VERSION = 1;
	TIME_UNIT = ns;
	PRINT_OPTIONS = "Print_options_version 6\
range_start 0ps\
range_end 5.0us\
width 1\
names_percentage 25\
comments 1\
grid_lines 1\
time_bars 1\
name_every_page 0\
expand_groups 0\
print_all 1";
	SIMULATION_TIME = 5000.0;
	GRID_PHASE = 0.0;
	GRID_PERIOD = 100.0;
	GRID_DUTY_CYCLE = 50;
}

SIGNAL("BER")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = BUS;
	WIDTH = 8;
	LSB_INDEX = 0;
	DIRECTION = OUTPUT;
	PARENT = "";
}

SIGNAL("BER[7]")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = OUTPUT;
	PARENT = "BER";
}

SIGNAL("BER[6]")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = OUTPUT;
	PARENT = "BER";
}

SIGNAL("BER[5]")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = OUTPUT;
	PARENT = "BER";
}

SIGNAL("BER[4]")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = OUTPUT;
	PARENT = "BER";
}

SIGNAL("BER[3]")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = OUTPUT;
	PARENT = "BER";
}

SIGNAL("BER[2]")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = OUTPUT;
	PARENT = "BER";
}

SIGNAL("BER[1]")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = OUTPUT;
	PARENT = "BER";
}

SIGNAL("BER[0]")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = OUTPUT;
	PARENT = "BER";
}

SIGNAL("InfoSeq")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = INPUT;
	PARENT = "";
}

SIGNAL("clk")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = INPUT;
	PARENT = "";
}

SIGNAL("result")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = INPUT;
	PARENT = "";
}

SIGNAL("rst")
{
	VALUE_TYPE = NINE_LEVEL_BIT;
	SIGNAL_TYPE = SINGLE_BIT;
	WIDTH = 1;
	LSB_INDEX = -1;
	DIRECTION = INPUT;
	PARENT = "";
}

TRANSITION_LIST("BER[7]")
{
	NODE
	{
		REPEAT = 1;
		LEVEL 0 FOR 5000.0;
	}
}

TRANSITION_LIST("BER[6]")
{
	NODE
	{
		REPEAT = 1;
		LEVEL 0 FOR 5000.0;
	}
}

TRANSITION_LIST("BER[5]")
{
	NODE
	{
		REPEAT = 1;
		LEVEL 0 FOR 5000.0;
	}
}

TRANSITION_LIST("BER[4]")
{
	NODE
	{
		REPEAT = 1;
		LEVEL 0 FOR 5000.0;
	}
}

TRANSITION_LIST("BER[3]")
{
	NODE
	{
		REPEAT = 1;
		LEVEL 0 FOR 3756.958;
		LEVEL 1 FOR 1200.0;
		LEVEL 0 FOR 43.042;
	}
}

TRANSITION_LIST("BER[2]")
{
	NODE
	{
		REPEAT = 1;
		LEVEL 0 FOR 1356.959;
		LEVEL 1 FOR 2400.0;
		LEVEL 0 FOR 1200.0;
		LEVEL 1 FOR 43.041;
	}
}

TRANSITION_LIST("BER[1]")
{
	NODE
	{
		REPEAT = 1;
		LEVEL 0 FOR 2556.989;
		LEVEL 1 FOR 1200.0;
		LEVEL 0 FOR 1200.0;
		LEVEL 1 FOR 43.011;
	}
}

TRANSITION_LIST("BER[0]")
{
	NODE
	{
		REPEAT = 1;
		LEVEL 0 FOR 1356.995;
		LEVEL 1 FOR 1200.0;
		LEVEL 0 FOR 2400.0;
		LEVEL 1 FOR 43.005;
	}
}

TRANSITION_LIST("InfoSeq")
{
	NODE
	{
		REPEAT = 1;
		NODE
		{
			REPEAT = 1;
			LEVEL 1 FOR 300.0;
			LEVEL 0 FOR 200.0;
			LEVEL 1 FOR 200.0;
			LEVEL 0 FOR 100.0;
			LEVEL 1 FOR 100.0;
			LEVEL 0 FOR 100.0;
		}
		LEVEL 1 FOR 200.0;
		LEVEL 0 FOR 3800.0;
	}
}

TRANSITION_LIST("clk")
{
	NODE
	{
		REPEAT = 1;
		LEVEL 1 FOR 50.0;
		LEVEL 0 FOR 50.0;
		NODE
		{
			REPEAT = 48;
			LEVEL 1 FOR 50.0;
			LEVEL 0 FOR 50.0;
		}
		LEVEL 1 FOR 50.0;
		LEVEL 0 FOR 50.0;
	}
}

TRANSITION_LIST("result")
{
	NODE
	{
		REPEAT = 1;
		LEVEL 1 FOR 200.0;
		LEVEL 0 FOR 300.0;
		LEVEL 1 FOR 300.0;
		LEVEL 0 FOR 4200.0;
	}
}

TRANSITION_LIST("rst")
{
	NODE
	{
		REPEAT = 1;
		LEVEL 0 FOR 50.0;
		LEVEL 1 FOR 50.0;
		LEVEL 0 FOR 4900.0;
	}
}

DISPLAY_LINE
{
	CHANNEL = "rst";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Binary;
	TREE_INDEX = 0;
	TREE_LEVEL = 0;
}

DISPLAY_LINE
{
	CHANNEL = "clk";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Binary;
	TREE_INDEX = 1;
	TREE_LEVEL = 0;
}

DISPLAY_LINE
{
	CHANNEL = "InfoSeq";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Binary;
	TREE_INDEX = 2;
	TREE_LEVEL = 0;
}

DISPLAY_LINE
{
	CHANNEL = "result";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Binary;
	TREE_INDEX = 3;
	TREE_LEVEL = 0;
}

DISPLAY_LINE
{
	CHANNEL = "BER";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Unsigned;
	TREE_INDEX = 4;
	TREE_LEVEL = 0;
	CHILDREN = 5, 6, 7, 8, 9, 10, 11, 12;
}

DISPLAY_LINE
{
	CHANNEL = "BER[7]";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Unsigned;
	TREE_INDEX = 5;
	TREE_LEVEL = 1;
	PARENT = 4;
}

DISPLAY_LINE
{
	CHANNEL = "BER[6]";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Unsigned;
	TREE_INDEX = 6;
	TREE_LEVEL = 1;
	PARENT = 4;
}

DISPLAY_LINE
{
	CHANNEL = "BER[5]";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Unsigned;
	TREE_INDEX = 7;
	TREE_LEVEL = 1;
	PARENT = 4;
}

DISPLAY_LINE
{
	CHANNEL = "BER[4]";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Unsigned;
	TREE_INDEX = 8;
	TREE_LEVEL = 1;
	PARENT = 4;
}

DISPLAY_LINE
{
	CHANNEL = "BER[3]";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Unsigned;
	TREE_INDEX = 9;
	TREE_LEVEL = 1;
	PARENT = 4;
}

DISPLAY_LINE
{
	CHANNEL = "BER[2]";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Unsigned;
	TREE_INDEX = 10;
	TREE_LEVEL = 1;
	PARENT = 4;
}

DISPLAY_LINE
{
	CHANNEL = "BER[1]";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Unsigned;
	TREE_INDEX = 11;
	TREE_LEVEL = 1;
	PARENT = 4;
}

DISPLAY_LINE
{
	CHANNEL = "BER[0]";
	EXPAND_STATUS = COLLAPSED;
	RADIX = Unsigned;
	TREE_INDEX = 12;
	TREE_LEVEL = 1;
	PARENT = 4;
}

TIME_BAR
{
	TIME = 12125;
	MASTER = TRUE;
}
;

performance.vwf - 源码说明

本页面展示了「用verilog编写的程序,用来计算误码率的,可以在编码和解码过程中用的到的!」中的 performance.vwf 源码文件,采用 VWF 编程语言编写,共 450 行代码。您可以在线阅读完整代码内容,也可以返回资源详情页下载完整源码包进行本地学习和开发。

虫虫下载站收录了大量与verilog相关的技术资源,包括源代码、技术文档、电路图等,是电子工程师和嵌入式开发者的专业学习平台。

⌨️ 快捷键说明

复制代码Ctrl + C
搜索代码Ctrl + F
全屏模式F11
增大字号Ctrl + =
减小字号Ctrl + -
显示快捷键?