info.yaml

--- 
# Tiny Tapeout project information
project:
  wokwi_id:    0        # If using wokwi, set this to your project's ID

# If using an HDL, set wokwi_id as 0 and uncomment and list your source files here. 
# Source files must be in ./src and you must list each source file separately
  source_files:        
    - tt_um_lif.v
    - lif.v
  top_module:  "tt_um_seven_segment_seconds"      # Put the name of your top module here, must start with "tt_um_". Make it unique by including your github username

# How many tiles your design occupies? A single tile is about 167x108 uM.
  tiles: "1x1"    # Valid values: 1x1, 1x2, 2x2, 3x2, 4x2 or 8x2

# Keep a track of the submission yaml
yaml_version: 4

# As everyone will have access to all designs, try to make it easy for someone new to your design to know what
# it does and how to operate it. This info will be automatically collected and used to make a datasheet for the chip.
#
# Here is a great example: https://github.com/davidsiaw/tt02-davidsiaw-stackcalc/blob/38c5647f83aad2aec675d566aa3d67b98f0aac81/info.yaml
documentation: 
  author:       "John Madden"      # Your name
  title:        "Leaky Integrate-and-Fire Demo"      # Project title
  language:     "Verilog" # other examples include Verilog, Amaranth, VHDL, etc
  description:  "LIF."      # Short description of what your project does

# Longer description of how the project works. You can use standard markdown format.
  how_it_works: |
      Uses a set of registers to divide the clock, and then some combinational logic
      to convert from binary to decimal for the display.

      Puts the bottom 8 bits of the counter on the bidirectional outputs.

      With all the inputs set to 0, the internal 24 bit compare is set to 10,000,000. This means the
      counter will increment by one each second.

      If any inputs are non zero, then the input will be used as an bits 11 to 18 of the 24 bit compare register.
      Example: setting the inputs to 00010000 will program 16384 into the compare register.
      With a 10MHz clock the counter will increment ~610 times per second.

# Instructions on how someone could test your project, include things like what buttons do what and how to set the clock if needed
  how_to_test:  |
      After reset, the counter should increase by one every second with a 10MHz input clock.
      Experiment by changing the inputs to change the counting speed.

# A description of what the inputs do (e.g. red button, SPI CLK, SPI MOSI, etc).
  inputs:               
    - current bit 11
    - current bit 12
    - current bit 13
    - current bit 14
    - current bit 15
    - current bit 16
    - current bit 17
    - current bit 18
# A description of what the outputs do (e.g. status LED, SPI MISO, etc)
  outputs:
    - membrane a
    - membrane b
    - membrane c
    - membrane d
    - membrane e
    - membrane f
    - membrane g
    - dot
# A description of what the bidirectional I/O pins do (e.g. I2C SDA, I2C SCL, etc)
  bidirectional:
    - second counter bit 0
    - second counter bit 1
    - second counter bit 2
    - second counter bit 3
    - second counter bit 4
    - second counter bit 5
    - second counter bit 6
    - second counter bit 7

# The following fields are optional
  tag:          "timer, test"      # comma separated list of tags: test, encryption, experiment, clock, animation, utility, industrial, pwm, fpga, alu, microprocessor, risc, riscv, sensor, signal generator, fft, filter, music, bcd, sound, serial, timer, random number generator, calculator, decoder, counter, puzzle, multiplier, game, oscillator,
  external_hw:  ""      # Describe any external hardware needed
  discord:      ""      # Your discord handle, used for communication and automatically assigning tapeout role after a submission
  doc_link:     ""      # URL to longer form documentation, eg the README.md in your repository
  clock_hz:     10000000       # Clock frequency in Hz (if required)
  picture:      ""      # relative path to a picture in your repository (must be 512kb or less)