319 lines
7.6 KiB
Plaintext
319 lines
7.6 KiB
Plaintext
m4_changequote(`⟨', `⟩')
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m4_changecom(⟨/*⟩, ⟨*/⟩)
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/*************** Precision **************
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* The control loop is designed around these values, but generally
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* does not hardcode them.
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*
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* Since I and P are precalculated outside of the loop, their
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* conversion to numbers the loop understands is done outside of
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* the loop and in the kernel.
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*
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* The 18-bit ADC is twos-compliment, -10.24V to 10.24V,
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* with 78μV per increment.
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* The 20-bit DAC is twos-compliment, -10V to 10V.
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*
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* The `P` constant has a minimum value of 1e-7 with a precision
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* of 1e-9, and a maxmimum value of 1.
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*
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* The `I` constant has a minimum value of 1e-4 with a precision
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* of 1e-6 and a maximum value of 100.
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*
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* Δt is cycles/100MHz. This makes Δt at least 10 ns, with a
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* maximum of 1 ms.
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*
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* [1 : sign][20: whole][43: fractional]
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*/
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module control_loop_math #(
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parameter CONSTS_WHOLE = 21,
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parameter CONSTS_FRAC = 43,
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m4_define(M4_CONSTS_WID, (CONSTS_WHOLE + CONSTS_FRAC))
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parameter CONSTS_SIZ=7,
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parameter ADC_WID = 18,
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parameter [M4_CONSTS_WID-1:0] SEC_PER_CYCLE = 'b10101011110011000,
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/* The conversion between the ADC bit (20/2**18) and DAC bit (20.48/2**20)
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* is 0.256.
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*/
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parameter [M4_CONSTS_WID-1:0] ADC_TO_DAC = 64'b0100000110001001001101110100101111000110101,
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parameter CYCLE_COUNT_WID = 18,
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parameter DAC_WID = 20
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m4_define(M4_E_WID, (DAC_WID + 1))
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) (
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input clk,
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input arm,
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input rst_L,
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output reg finished,
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input signed [ADC_WID-1:0] setpt,
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input signed [ADC_WID-1:0] measured,
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input signed [M4_CONSTS_WID-1:0] cl_P,
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input signed [M4_CONSTS_WID-1:0] cl_I,
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input signed [CYCLE_COUNT_WID-1:0] cycles,
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input signed [M4_E_WID-1:0] e_prev,
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input signed [M4_CONSTS_WID-1:0] adjval_prev,
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input signed [DAC_WID-1:0] stored_dac_val,
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`ifdef DEBUG_CONTROL_LOOP_MATH
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output reg [M4_CONSTS_WID-1:0] dt_reg,
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output reg [M4_CONSTS_WID-1:0] idt_reg,
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output reg [M4_CONSTS_WID-1:0] epidt_reg,
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output reg [M4_CONSTS_WID-1:0] ep_reg,
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`endif
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output reg signed [M4_E_WID-1:0] e_cur,
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output signed [DAC_WID-1:0] new_dac_val,
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output signed [M4_CONSTS_WID-1:0] adj_val
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);
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/*******
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* Multiplier segment.
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* Multiplies two 64 bit numbers and right-saturate + truncates it
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* to be a 64 bit output, according to fixed-point rules.
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*/
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reg signed [M4_CONSTS_WID-1:0] a1;
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reg signed [M4_CONSTS_WID-1:0] a2;
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/* verilator lint_off UNUSED */
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wire signed [M4_CONSTS_WID+M4_CONSTS_WID-1:0] out_untrunc;
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wire mul_fin;
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reg mul_arm = 0;
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boothmul #(
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.A1_LEN(M4_CONSTS_WID),
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.A2_LEN(M4_CONSTS_WID),
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.A2LEN_SIZ(CONSTS_SIZ)
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) multiplier (
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.a1(a1),
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.a2(a2),
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.clk(clk),
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.rst_L(rst_L),
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.outn(out_untrunc),
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.fin(mul_fin),
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.arm(mul_arm)
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);
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/****************************
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* QX.Y * QX.Y = Q(2X).(2Y)
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* This right-truncation gets rid of the lowest Y bits.
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* Q(2X).Y
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*/
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m4_define(M4_OUT_RTRUNC_WID, (M4_CONSTS_WID+M4_CONSTS_WID-CONSTS_FRAC))
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wire signed [M4_OUT_RTRUNC_WID-1:0] out_rtrunc
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= out_untrunc[M4_CONSTS_WID+M4_CONSTS_WID-1:CONSTS_FRAC];
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wire signed [M4_CONSTS_WID-1:0] mul_out;
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/***************************
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* Saturate higher X bits away.
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* Q(2X).Y -> QX.Y
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*/
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intsat #(
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.IN_LEN(M4_OUT_RTRUNC_WID),
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.LTRUNC(CONSTS_WHOLE)
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) multiplier_saturate (
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.inp(out_rtrunc),
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.outp(mul_out)
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);
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/*************************
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* Safely get rid of high bit in addition.
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************************/
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reg signed [M4_CONSTS_WID+1-1:0] add_sat;
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wire signed [M4_CONSTS_WID-1:0] saturated_add;
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intsat #(
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.IN_LEN(M4_CONSTS_WID + 1),
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.LTRUNC(1)
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) addition_saturate (
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.inp(add_sat),
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.outp(saturated_add)
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);
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/************************
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* Safely truncate down adjustment value.
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***********************/
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reg signed [CONSTS_WHOLE-1:0] adj_sat;
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wire signed [DAC_WID-1:0] adj_final;
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intsat #(
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.IN_LEN(CONSTS_WHOLE),
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.LTRUNC(CONSTS_WHOLE - DAC_WID)
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) adj_saturate (
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.inp(adj_sat),
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.outp(adj_final)
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);
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/************************
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* Safely calculate new DAC value.
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************************/
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reg signed [DAC_WID+1-1:0] add_sat_dac;
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intsat #(
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.IN_LEN(DAC_WID+1),
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.LTRUNC(1)
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) dac_saturate (
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.inp(add_sat_dac),
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.outp(new_dac_val)
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);
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localparam WAIT_ON_ARM = 0;
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localparam CALCULATE_ERR = 9;
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localparam CALCULATE_DAC_E = 7;
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localparam WAIT_ON_CALCULATE_DT = 1;
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localparam CALCULATE_IDT = 2;
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localparam CALCULATE_EPIDT = 3;
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localparam CALCULATE_EP = 4;
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localparam CALCULATE_A_PART_1 = 5;
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localparam CALCULATE_A_PART_2 = 6;
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localparam CALCULATE_NEW_DAC_VALUE_PART_1 = 10;
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localparam CALCULATE_NEW_DAC_VALUE_PART_2 = 11;
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localparam WAIT_ON_DISARM = 8;
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reg [4:0] state = WAIT_ON_ARM;
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reg signed [M4_CONSTS_WID+1-1:0] tmpstore = 0;
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wire signed [M4_CONSTS_WID-1:0] tmpstore_view = tmpstore[M4_CONSTS_WID-1:0];
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always @ (posedge clk) begin
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if (!rst_L) begin
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state <= WAIT_ON_ARM;
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a1 <= 0;
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finished <= 0;
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mul_arm <= 0;
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a2 <= 0;
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e_cur <= 0;
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`ifdef DEBUG_CONTROL_LOOP_MATH
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dt_reg <= 0;
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idt_reg <= 0;
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epidt_reg <= 0;
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ep_reg <= 0;
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`endif
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add_sat <= 0;
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adj_val <= 0;
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tmpstore <= 0;
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end else case (state)
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WAIT_ON_ARM:
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if (arm) begin
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a1[CONSTS_FRAC-1:0] <= 0;
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a1[CONSTS_FRAC+ADC_WID + 1-1:CONSTS_FRAC] <= setpt - measured;
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state <= CALCULATE_ERR;
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end else begin
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finished <= 0;
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mul_arm <= 0;
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end
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CALCULATE_ERR: begin
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/* Sign-extend */
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a1[M4_CONSTS_WID-1:CONSTS_FRAC + ADC_WID + 1] <=
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{(M4_CONSTS_WID-(CONSTS_FRAC + ADC_WID + 1)){a1[ADC_WID+1-1+CONSTS_FRAC]}};
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a2 <= ADC_TO_DAC;
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mul_arm <= 1;
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state <= CALCULATE_DAC_E;
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end
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CALCULATE_DAC_E:
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if (mul_fin) begin
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/* Discard other bits. This works without saturation because
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* CONSTS_WHOLE = E_WID. */
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e_cur <= mul_out[M4_CONSTS_WID-1:CONSTS_FRAC];
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a1 <= SEC_PER_CYCLE;
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/* No sign extension, cycles is positive */
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a2 <= {{(CONSTS_WHOLE - CYCLE_COUNT_WID){1'b0}}, cycles, {(CONSTS_FRAC){1'b0}}};
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mul_arm <= 0;
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state <= WAIT_ON_CALCULATE_DT;
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end
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WAIT_ON_CALCULATE_DT:
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if (!mul_arm) begin
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mul_arm <= 1;
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end else if (mul_fin) begin
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mul_arm <= 0;
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`ifdef DEBUG_CONTROL_LOOP_MATH
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dt_reg <= mul_out;
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`endif
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a1 <= mul_out; /* a1 = Δt */
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a2 <= cl_I;
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state <= CALCULATE_IDT;
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end
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CALCULATE_IDT:
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if (!mul_arm) begin
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mul_arm <= 1;
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end else if (mul_fin) begin
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mul_arm <= 0;
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add_sat <= (mul_out + cl_P);
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`ifdef DEBUG_CONTROL_LOOP_MATH
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idt_reg <= mul_out;
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`endif
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a2 <= {{(CONSTS_WHOLE-M4_E_WID){e_cur[M4_E_WID-1]}},e_cur, {(CONSTS_FRAC){1'b0}}};
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state <= CALCULATE_EPIDT;
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end
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CALCULATE_EPIDT:
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if (!mul_arm) begin
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a1 <= saturated_add;
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mul_arm <= 1;
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end else if (mul_fin) begin
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mul_arm <= 0;
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tmpstore <= {mul_out[M4_CONSTS_WID-1],mul_out};
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`ifdef DEBUG_CONTROL_LOOP_MATH
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epidt_reg <= mul_out;
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`endif
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a1 <= cl_P;
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a2 <= {{(CONSTS_WHOLE-M4_E_WID){e_prev[M4_E_WID-1]}},e_prev, {(CONSTS_FRAC){1'b0}}};
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state <= CALCULATE_EP;
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end
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CALCULATE_EP:
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if (!mul_arm) begin
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mul_arm <= 1;
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end else if (mul_fin) begin
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`ifdef DEBUG_CONTROL_LOOP_MATH
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ep_reg <= mul_out;
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`endif
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mul_arm <= 0;
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add_sat <= (tmpstore_view - mul_out);
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state <= CALCULATE_A_PART_1;
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end
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CALCULATE_A_PART_1: begin
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tmpstore <= saturated_add + adjval_prev;
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state <= CALCULATE_A_PART_2;
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end
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CALCULATE_A_PART_2: begin
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add_sat <= tmpstore;
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state <= CALCULATE_NEW_DAC_VALUE_PART_1;
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end
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CALCULATE_NEW_DAC_VALUE_PART_1: begin
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adj_sat <= saturated_add[M4_CONSTS_WID-1:CONSTS_FRAC];
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adj_val <= saturated_add;
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state <= CALCULATE_NEW_DAC_VALUE_PART_2;
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end
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CALCULATE_NEW_DAC_VALUE_PART_2: begin
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add_sat_dac <= adj_final + stored_dac_val;
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state <= WAIT_ON_DISARM;
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end
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WAIT_ON_DISARM: begin
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adj_val <= saturated_add;
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if (!arm) begin
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state <= WAIT_ON_ARM;
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finished <= 0;
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end else begin
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finished <= 1;
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end
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end
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endcase
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end
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`ifdef VERILATOR
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initial begin
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$dumpfile("control_loop_math.fst");
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$dumpvars;
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end
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`endif
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endmodule
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