digital-logic fpga hardware-design modelsim quartus system-verilog verilog verilog-testbenches

Verilog CLOCK

Digital Logic CLOCK - designed with System Verilog and implemented on Altera's DE1-SOC

General

The idea of this project was to create a simple System Verilog design for a AM/PM clock based on digital logic on an FPGA.

view of the DE1-SOC CLOCK Implementation

Navigating Directories

Verilog: VERILOG IN HERE! This directory includes two folders. The Modules include the System-Verilog modules. The modules included are: card_7seg.sv, BCD.sv, CLOCK.sv, and clock_top.sv (top-level-module). The Testbenches folder includes all of the corresponding testbenches.
Media: Includes photos of the project, diagrams and a short video of the working design on the FPGA.
Simulation: Includes .do files. regress.do includes, when run on Modelsim, just load the top level rtl testbench and runs it. The rest of the .do files load the wave signals to the relevant testbenches
Synthesis: The directory includes only 2 files. The first, CLOCK.sof if the .sof file you can load directly onto the DE1-SOC board. The other is the DE1-SOC pin assignment file- for the users ease-of-use.

Project Challenges

Some of the goals of the project were:

Asynchronous Design (multiple clocks used for state transition and for manual time configuration.
System Verilog Practice
Advanced debugging techniques practice (e.g SignalTap)
For fun! (To show friends what you can do with hardware design on an FPGA with just 1 driving signal - 50MHz crystal).

Design Description

The design of the clock is based on simple busses, flip-flops, and mux's. The whole system can be seen as a state machine system with two states represented by the TMOD bit.

TMOD == 1'b0 : CLK_RUN - this means that the clock is running and incrementing regularly with time
TMOD == 1'b1 : CLK_SET - this means that the time has stopped and that the minutes and hours can be incremented manually ** More on the states here

Registers:
1. 26-bit counter. This register is intended to count from [$0$ to $50*10^6$] which is $26'b10111110101111000010000000$ in binary and is defined in the `CLOCK.sv` module as a macro `define Fifty_M
2. (X2) 6-bit registers for Seconds and Minutes - 6-bits for ranges of [0:59]
3. (X1) 5-bit register for Hours - 5-bits for range of [0:23].
4. State Flip-Flop register called TMOD - defines the state as above

States

CLK_RUN state:
The 50MHz clk will increment the counter until $50*10E6$ at which points the inc_min flag will be raised with will increment the seconds register. The seconds register increments until it gets to $59$ at which point in resets to 0 and the inc_min flag will be raised. The minutes register increments in the same way, and once the minutes resets to 0 the inc_hr flag will be raised. The hours register increments until $23$ and then resets to 0. Transitioning to the CLK_SET state occurs by pressing the physical button on the FPGA (KEY[3]).

CLK_SET state:
The 50MHz signal is disconnected from the circuit, the counter stops incrementing. In this state the seconds will stop and the inc_min and inc_hr signals will be determined by 2 physical buttons on the FPGA (KEY[0] and KEY[1]). Pressing one of these will increment either the minutes or the hour. Returning to the CLK_RUN state occurs by pressing the physical button on the FPGA (KEY[3]).

Hardware Design Diagram

RTL Hardware Diagram Sketch

RTL Netlist View Tool

Quartus RTL Netlist Viewer - CLOCK Module

Quartus RTL Netlist Viewer Top-level Module

About

This project was a nice idea I had to build a digital logic clock on the DE1-SOC FPGA, while practicing System-verilog, Asynchronous design, and advanced debugging techniques