204 IEEE | 24-Bit Serial Fixed-Point Binary Divider
204 : IEEE | 24-Bit Serial Fixed-Point Binary Divider
- Author: Miguel Angel Tobón Morales
- Description: Serial divider implemented in Verilog for 24-bit fixed-point numbers with 23 fractional bits, capable of performing normalized binary divisions within an approximate range of 0 to 1.9999999.
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- Clock: 50000000 Hz
IEEE | 24-Bit Digit-Serial Fixed-Point Divider
Project description
A 24-bit digit-serial restoring divider implemented in Verilog for the Tiny Tapeout (SKY130) flow. The design computes fixed-point quotients with 23 fractional bits using a repeatable micro-step performed by a compact datapath and a small FSM.
Top-level:
tt_um_digit_serial_divider
Core modules:
digit_serial_dividerdigit_serial_divider_core(which instantiatesdatapathandcontrolpath)
How does it work?
Overview
- The interface accepts operand bits serially. The wrapper captures 24-bit fixed-point values for dividend and divisor (LSB-first) while a start signal is asserted.
Compute flow (general)
- Load phase: the controller enables serial loading of both operands into internal shift/buffer registers. When loading completes, the core is triggered to start computation.
- Iterative compute phase: the control FSM sequences a repeated micro-step for N = 24 iterations. Each micro-step:
- Aligns or shifts the current remainder and introduces the next dividend bit into the remainder path.
- Subtracts the aligned divisor from the extended remainder to form a candidate residue.
- Uses the subtraction sign (borrow flag) to decide whether to accept the candidate residue or keep the previous remainder. The accepted result determines the quotient bit for that iteration.
- Stores the quotient bit into a serial shift register.
- Completion: a small counter tracks the number of micro-steps. After N iterations the controller signals DONE and the computed 24-bit quotient is available in parallel inside the core and can be shifted out serially by the top-level wrapper.
Datapath (conceptual)
- A remainder register wider than the operand (one extra bit) holds the running residue.
- A register holds the divisor aligned to the remainder width.
- A dedicated subtractor produces the candidate residue and a borrow flag used by the decision logic.
- A residue multiplexer selects either the candidate or the previous remainder depending on the subtractor result.
- A shift register collects quotient bits serially and presents the parallel quotient after completion.
Control (conceptual)
- The FSM has three main phases: start/load, compute, and count/check. It toggles control signals to enable operand loading, remainder updates, and quotient shifting. Transitions depend on the start input, the subtractor borrow flag, and the iteration counter overflow.
How to test it?
Follow this exact procedure:
-
Apply reset: assert
rst = 1to initialize internal registers; after the reset period deassertrst. -
Convert operands to 24-bit fixed-point (23 fractional bits):
value_int = round(value_real * 2**23) -
Maintain
START = 1while shifting 24 bits of X and Y LSB-first ontoui_in[0]andui_in[1](one clock per bit). -
Lower
STARTwhen the 24-bit load is complete. -
Wait for
DONE = 1. -
Read
qfor 24 clock cycles whileDONEis active to capture the quotient bits (LSB-first). -
Wait for
DONEto return to0before starting another operation.
Example
- Scaled inputs:
X_int = round(1.789634233478 * 2**23),Y_int = round(1.974231473301 * 2**23) - Expected quotient (real):
1.789634233478 / 1.974231473301 = 0.906496644020081
Verification notes
DONEmust assert after 24 micro-iterations.- The captured serial quotient must match the fixed-point result within the 23-bit fractional resolution.
Files of interest
- src/tt_um_digit_serial_divider.v
- src/digit_serial_divider.v
- src/digit_serial_divider_core.v
- src/datapath.v
- src/controlpath.v
- src/fsm.v
- dv/tb_digit_serial_divider.v
External Hardware
To test this design on silicon, the most practical approach is to use an external microcontroller as a test bench.
Recommended setup:
Microcontroller options: Arduino, Raspberry Pi Pico, STM32, ESP32, or any platform capable of GPIO bit-banging.
Microcontroller responsibilities:
- Generate and control the clock (
clk) signal. - Drive the reset signal (
rst). - Assert and manage the start signal (
ui_in[2]). - Serially present operand bits on
ui_in[0](X) andui_in[1](Y) with precise timing. - Monitor and read the DONE signal (
uo_out[1]). - Capture quotient bits from
uo_out[0]over N clock cycles while DONE is asserted.
The microcontroller can log results, compare against expected fixed-point quotients, and report pass/fail status for each test vector.
IO
| # | Input | Output | Bidirectional |
|---|---|---|---|
| 0 | X | Q | |
| 1 | Y | DONE | |
| 2 | START | ||
| 3 | |||
| 4 | |||
| 5 | |||
| 6 | |||
| 7 |