---------------------------------------------------------------------------------- -- Project: YASG (Yet another signal generator) -- Project Page: https://github.com/id101010/vhdl-yasg/ -- Authors: Aaron Schmocker & Timo Lang -- License: GPL v3 -- Create Date: 11:09:53 05/16/2016 ---------------------------------------------------------------------------------- library IEEE; use IEEE.STD_LOGIC_1164.ALL; use IEEE.NUMERIC_STD.ALL; use IEEE.MATH_REAL.ALL; use work.helpers.all; entity dds is Generic (clk_freq: natural:= 50000000; freq_res: natural:=17; -- width of frequency input (log2(max_freq)) adc_res: natural:=12; -- width of the ouput signal (=adc resolution) acc_res: natural:=32; -- width of the phase accumulator phase_res: natural:=10); -- effective phase resolution for sin lookup table Port ( clk : in STD_LOGIC; freq : in unsigned (freq_res-1 downto 0); form : in unsigned (1 downto 0); amp : out unsigned (adc_res-1 downto 0)); end dds; architecture Behavioral of dds is signal m, idx : unsigned(acc_res -1 downto 0):= (others => '0'); signal idx_phase : unsigned(phase_res-1 downto 0) := (others => '0'); signal amp_rect, amp_saw, amp_tria, amp_sin : unsigned (adc_res-1 downto 0); type storage is array (((2**phase_res)/4)-1 downto 0) of unsigned (adc_res-2 downto 0); --type storage is array (((2**phase_res))-1 downto 0) of unsigned (adc_res-1 downto 0); function gen_sin_wave return storage is variable temp : storage; begin forLoop: for i in 0 to temp'high loop temp(i) := to_unsigned(integer(real((2**(adc_res-1))-1)*sin((real(i)*MATH_PI/2.0)/real(temp'high))),adc_res-1); --temp(i) := to_unsigned(integer(real(2**(adc_res-1) -1) + real((2**(adc_res-1))-1)*sin((real(i)*MATH_PI*2.0)/real(temp'high))),adc_res); end loop; return temp; end function gen_sin_wave; constant sin_wave : storage := gen_sin_wave; begin -- m = fout*(2^n)/fclk = fout*((2^n)*(2^k)/fclk)/(2^k) with k=ceil(log2(fclk)), n=acc_res m <= resize( (resize(freq,64) * (shift_left(to_unsigned(1,64),acc_res + log2_int(clk_freq)) / clk_freq)) /to_unsigned(2**log2_int(clk_freq),64),acc_res); amp_rect <= to_unsigned(0,adc_res) when idx(acc_res-1)='0' else to_unsigned((2**adc_res)-1,adc_res); amp_saw <= idx(acc_res -1 downto acc_res - adc_res); amp_tria <= idx(acc_res -2 downto acc_res - adc_res) & "0" when idx(acc_res-1)='0' else ((2**adc_res)-1)- (idx(acc_res -2 downto acc_res - adc_res) & "0"); idx_phase <= idx(acc_res -1 downto acc_res - phase_res); --amp_sin <= sin_wave(to_integer(idx_phase)); amp_sin <= to_unsigned((2**(adc_res-1)) - 1,adc_res) + sin_wave(to_integer(idx_phase(phase_res-3 downto 0))) when idx_phase(phase_res-1 downto phase_res-2)="00" else to_unsigned((2**(adc_res-1)) - 1,adc_res) + sin_wave(to_integer(((2**(phase_res-2))-1) - idx_phase(phase_res-3 downto 0))) when idx_phase(phase_res-1 downto phase_res-2)="01" else to_unsigned((2**(adc_res-1)) - 1,adc_res) - sin_wave(to_integer(idx_phase(phase_res-3 downto 0))) when idx_phase(phase_res-1 downto phase_res-2)="10" else to_unsigned((2**(adc_res-1)) - 1,adc_res) - sin_wave(to_integer(((2**(phase_res-2))-1) - idx_phase(phase_res-3 downto 0))); amp <= to_unsigned(0,adc_res) when freq = to_unsigned(0,freq_res) else amp_rect when form = "00" else amp_saw when form ="01" else amp_tria when form = "10" else amp_sin; P1: process(clk) begin if(rising_edge(clk)) then idx <= (idx+m); end if; end process P1; end Behavioral;