8.7 KiB
8.7 KiB
基础-3-数码管实验
在许多项目设计中,我们通常需要一些显示设备来显示我们需要的信息,可以选择的显示设备有很多,而数码管是使用最多,最简单的显示设备之一。
3.1 章节导读
本章将通过数码管驱动实验讲解FPGA数字系统中重要的"选通控制"概念。读者将学习到:
- 数码管工作原理与动态扫描技术
- 多路复用(Multiplexing)设计方法
- 参数化模块设计技巧
- 外设驱动时序规划
- ASCII到段码的转换原理
实验将使用Verilog HDL实现一个支持8位数码管显示、包含字符动态滚动和选通控制的完整系统。
3.2 理论学习
3.2.1 数码管结构
- 7段数码管组成:A-G段+DP小数点
- 共阳/共阴类型区分(本实验采用共阳型,低电平有效)
3.2.2 动态扫描原理
显示周期 = 刷新周期 × 数码管数量
人眼视觉暂留效应(>60Hz)
扫描频率计算公式:f_scan = f_clk / CLK_CYCLE
3.2.3 关键技术
- 时分复用:分时选通数码管
- 段码生成:ASCII字符到七段码转换
- 消隐处理:消除切换时的视觉残留
3.2.4 设计指标
| 参数 | 值 | 说明 |
|---|---|---|
| 位数 | 8 | 数码管数量 |
| 频率 | 200Hz | 单管刷新频率 |
| 分辨率 | 8bit | 段码控制(含小数点) |
3.2 实战演练
3.3.1 系统架构
系统框图:
[Top模块] → [显示驱动模块] → [选通控制模块]
↖ ASCII数据生成 ↙ 时钟分频
3.3.2 模块设计
led_display_selector
module led_display_selector #(
parameter NUM = 4,
parameter VALID_SIGNAL = 1'b0,
parameter CLK_CYCLE = 1000
)(
input wire clk,
input wire rstn,
input wire [NUM*8-1:0] led_in,
output reg [7:0] led_display_seg,//[DP,G,F,E,D,C,B,A]
output reg [NUM-1:0] led_display_sel
);
reg [31:0] clk_cnt;
always @(posedge clk or negedge rstn) begin
if (!rstn) clk_cnt <= 0;
else if(clk_cnt == CLK_CYCLE) clk_cnt <= 0;
else clk_cnt <= clk_cnt + 1;
end
wire seg_change = (clk_cnt == CLK_CYCLE) ? 1'b1 : 1'b0;
always @(posedge clk or negedge rstn) begin
if(!rstn) led_display_sel <= {{(NUM-1){~VALID_SIGNAL}}, VALID_SIGNAL};
else if (seg_change) led_display_sel <= {led_display_sel[NUM-2:0], led_display_sel[NUM-1]};
else led_display_sel <= led_display_sel;
end
integer i;
always @(*) begin
for(i=0;i<NUM;i=i+1) begin
if(led_display_sel[NUM-1-i] == VALID_SIGNAL)
led_display_seg = led_in[i*8 +: 8] ^ ({8{~VALID_SIGNAL}});
end
end
endmodule //led_display_ctrl
led_display_driver
module led_display_driver(// 8个数码管显示,阳极管(在selector中已经做了阴阳处理)
input wire clk,
input wire rstn,
input wire [8*8-1:0] assic_seg, //ASSIC coding
input wire [7:0] seg_point, //显示小数点
output wire [7:0] led_display_seg,
output wire [7:0] led_display_sel
);
reg [8*8-1:0] led_in;
integer i;
always @(*) begin
led_in = 0;
for(i=0;i<8;i=i+1) begin //led_in[i*8 +: 8] <---> assic_seg[i*8 +: 8]
case (assic_seg[i*8 +: 8])
"0": led_in[i*8 +: 8] = (8'h3f) | {seg_point[i],7'b0};
"1": led_in[i*8 +: 8] = (8'h06) | {seg_point[i],7'b0};
"2": led_in[i*8 +: 8] = (8'h5b) | {seg_point[i],7'b0};
"3": led_in[i*8 +: 8] = (8'h4f) | {seg_point[i],7'b0};
"4": led_in[i*8 +: 8] = (8'h66) | {seg_point[i],7'b0};
"5": led_in[i*8 +: 8] = (8'h6d) | {seg_point[i],7'b0};
"6": led_in[i*8 +: 8] = (8'h7d) | {seg_point[i],7'b0};
"7": led_in[i*8 +: 8] = (8'h07) | {seg_point[i],7'b0};
"8": led_in[i*8 +: 8] = (8'h7f) | {seg_point[i],7'b0};
"9": led_in[i*8 +: 8] = (8'h6f) | {seg_point[i],7'b0};
"A","a": led_in[i*8 +: 8] = (8'h77) | {seg_point[i],7'b0};
"B","b": led_in[i*8 +: 8] = (8'h7c) | {seg_point[i],7'b0};
"C","c": led_in[i*8 +: 8] = (8'h39) | {seg_point[i],7'b0};
"D","d": led_in[i*8 +: 8] = (8'h5e) | {seg_point[i],7'b0};
"E","e": led_in[i*8 +: 8] = (8'h79) | {seg_point[i],7'b0};
"F","f": led_in[i*8 +: 8] = (8'h71) | {seg_point[i],7'b0};
"G","g": led_in[i*8 +: 8] = (8'h3d) | {seg_point[i],7'b0};
"H","h": led_in[i*8 +: 8] = (8'h76) | {seg_point[i],7'b0};
"I","i": led_in[i*8 +: 8] = (8'h0f) | {seg_point[i],7'b0};
"J","j": led_in[i*8 +: 8] = (8'h0e) | {seg_point[i],7'b0};
"K","k": led_in[i*8 +: 8] = (8'h75) | {seg_point[i],7'b0};
"L","l": led_in[i*8 +: 8] = (8'h38) | {seg_point[i],7'b0};
"M","m": led_in[i*8 +: 8] = (8'h37) | {seg_point[i],7'b0};
"N","n": led_in[i*8 +: 8] = (8'h54) | {seg_point[i],7'b0};
"O","o": led_in[i*8 +: 8] = (8'h5c) | {seg_point[i],7'b0};
"P","p": led_in[i*8 +: 8] = (8'h73) | {seg_point[i],7'b0};
"Q","q": led_in[i*8 +: 8] = (8'h67) | {seg_point[i],7'b0};
"R","r": led_in[i*8 +: 8] = (8'h31) | {seg_point[i],7'b0};
"S","s": led_in[i*8 +: 8] = (8'h49) | {seg_point[i],7'b0};
"T","t": led_in[i*8 +: 8] = (8'h78) | {seg_point[i],7'b0};
"U","u": led_in[i*8 +: 8] = (8'h3e) | {seg_point[i],7'b0};
"V","v": led_in[i*8 +: 8] = (8'h1c) | {seg_point[i],7'b0};
"W","w": led_in[i*8 +: 8] = (8'h7e) | {seg_point[i],7'b0};
"X","x": led_in[i*8 +: 8] = (8'h64) | {seg_point[i],7'b0};
"Y","y": led_in[i*8 +: 8] = (8'h6e) | {seg_point[i],7'b0};
"Z","z": led_in[i*8 +: 8] = (8'h59) | {seg_point[i],7'b0};
" ": led_in[i*8 +: 8] = (8'h00) | {seg_point[i],7'b0};
"-": led_in[i*8 +: 8] = (8'h40) | {seg_point[i],7'b0};
"_": led_in[i*8 +: 8] = (8'h08) | {seg_point[i],7'b0};
"=": led_in[i*8 +: 8] = (8'h48) | {seg_point[i],7'b0};
"+": led_in[i*8 +: 8] = (8'h5c) | {seg_point[i],7'b0};
"(": led_in[i*8 +: 8] = (8'h39) | {seg_point[i],7'b0};
")": led_in[i*8 +: 8] = (8'h0F) | {seg_point[i],7'b0};
default: led_in[i*8 +: 8] = (8'h00) | {seg_point[i],7'b0};
endcase
end
end
led_display_selector #(
.NUM ( 8 ),
.VALID_SIGNAL ( 1'b0 ), //阳极管,低电平亮
.CLK_CYCLE ( 5000 ))
u_led_display_selector(
.clk ( clk ),
.rstn ( rstn ),
.led_in ( led_in ),
.led_display_seg ( led_display_seg ),
.led_display_sel ( led_display_sel )
);
endmodule //moduleName
led_display_top
module led_diaplay_top(
//system io
input wire external_clk ,
input wire external_rstn,
//led display io
output wire [7:0] led_display_seg,
output wire [7:0] led_display_sel
);
reg [43*8-1:0] assic_seg;
reg [7:0] seg_point;
reg [31:0] clk_cnt;
always @(posedge external_clk or negedge external_rstn) begin
if(!external_rstn) clk_cnt <= 0;
else clk_cnt <= clk_cnt + 1;
end
always @(posedge external_clk or negedge external_rstn) begin
if(!external_rstn) begin
assic_seg <= "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ -_=+()";
seg_point <= 8'b00000001;
end else if({clk_cnt[24]==1'b1} && (clk_cnt[23:0]==25'b0))begin
assic_seg <= {assic_seg[8*43-8-1:0], assic_seg[8*43-1 -: 8]};
seg_point <= {seg_point[6:0], seg_point[7]};
end else begin
assic_seg <= assic_seg;
seg_point <= seg_point;
end
end
led_display_driver u_led_display_driver(
.clk ( external_clk ),
.rstn ( external_rstn ),
.assic_seg ( assic_seg[8*43-1 -: 8*8] ),
.seg_point ( seg_point ),
.led_display_seg ( led_display_seg ),
.led_display_sel ( led_display_sel )
);
endmodule //led_diaplay_top
3.3.3 上板验证步骤
- 设置参数:CLK_CYCLE=5000(对应200Hz扫描频率)
- 绑定管脚:连接数码管段选/位选信号
- 观察现象:字符"01234567"应稳定显示
- 修改assic_seg初始值验证滚动功能
3.4 章末总结
关键收获:
- 掌握动态扫描消除器件闪烁的原理
- 理解参数化设计(NUM/VALID_SIGNAL)的优势
- 学习时序控制中计数器的重要作用
- 实践ASCII到硬件编码的转换方法
设计亮点:
- 支持阴阳极自动适配(通过VALID_SIGNAL参数)
- 字符环形缓冲区实现无缝滚动
- 参数化设计增强模块复用性
3.5 拓展训练
结合流水灯实验和数码管实验:数码管显示数字,标识出当前流水到了哪一个灯