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Friday, 8 June 2018

Verilog code for Interpolation filter with factor 2



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Interpolation filter Design using Verilog Code.




 

interpolation factor = 2
coefficient number =10 ={1,0,0,0,0,0,0,0,0,0}
input sequence seq_in = {1,2,3,4,5,6,7,8,9....}
output sequence seq_out ={1,0,2,0,3,0,4,0,5,0,6....}
the below code helps us to get the interpolated sequence using interpolation factor 2
it uses the state machine and it is active low reset
every 10th clock the output is generated


 
 
 
 
//---------------function_multi.v------------------multiplication_function-------------------//
//---------------------used the function for multiplication---------------------------------//
 
module multiplication (input1 ,input2,output,clk,rst);
 
parameter WIDTH_IN=12                         ;
parameter WIDTH_OUT=20                        ;

input       [WIDTH_IN-1:0]input1              ;
input       [WIDTH_IN-1:0]input2              ;
input       clk,rst                           ;

output       [WIDTH_OUT-1:0]output            ;
 
always@(posedge clk)
begin 
if(!rst)
ouput<=0                                      ;
else
output<=input1*input2                       ;
end 

endmodule
  
//-------------------------------------------------------------------------------------------//
//-------------------------------------------------------------------------------------------//
//--------------------------------interpolTION-----------------------------------------------// 
 
 
 `include "function_multi.v"                       //multiplication function

//-----------------------------------------------------------------------------//
 
module interpolation(
         seq_in                           ,//input sequence
         seq_out                          ,//interpolated output sequence
         rst                              ,//reset
         clk                               //system clock
); 
 
 
//-----------------------------------parameter------------------------------------------------//
 
parameter WIDTH_IN=12                       ;//input width
parameter WIDTH_OUT=18                      ;//output width

 
//----------------------------------COEFFICENTs-----------------------------------------------//
 
 
parameter signed H1= 1                      ;//coefficents from h1 to h10
parameter signed H2= 0                      ;
parameter signed H3= 0                      ;
parameter signed H4= 0                      ;
parameter signed H5= 0                      ;
parameter signed H6= 0                      ;
parameter signed H7= 0                      ;
parameter signed H8= 0                      ;
parameter signed H9= 0                      ;
parameter signed H10=0                      ;


//-----------------------------------------REGISTER-------------------------------------------//

reg signed  [WIDTH_IN-1:0] q1, q2, q3, q4, q5, q6, q7, q8, q9,q10            ;//shift registers 


reg signed [WIDTH_OUT-1:0]accum1            ;//accumulator for 1st clock of operation
reg signed [WIDTH_OUT-1:0]accum2            ;//accumulator for 2nd clock of operation
reg signed [WIDTH_OUT-1:0]accum3            ;//accumulator for 3rd clock of operation
reg signed [WIDTH_OUT-1:0]accum4            ;//accumulator for 4th clock of operation
reg signed [WIDTH_OUT-1:0]accum5            ;//accumulator for 5th clock of operation
reg signed [WIDTH_OUT-1:0]accum6            ;//accumulator for 6th clock of operation
reg signed [WIDTH_OUT-1:0]accum7            ;//accumulator for 7st clock of operation
reg signed [WIDTH_OUT-1:0]accum8            ;//accumulator for 8th clock of operation
reg signed [WIDTH_OUT-1:0]accum9            ;//accumulator for9th clock of operation
reg signed [WIDTH_OUT-1:0]accum10           ;//accumulator for 10th clock of operation
                
reg signed [WIDTH_IN-1:0]in1m1,in2m1        ;//input to 1st multiplier
reg [11:0]out                               ;//register for ring counter
reg [3:0]state=4'b0001                      ;//state register 
 
 

//---------------------------------------wire-------------------------------------------------//

 
wire  [WIDTH_OUT-1:0]out_add                    ;//output from the multiplier


 
//----------------------------------------input------------------------------------------------//

 input signed [WIDTH_IN-1:0]seq_in               ;//input sequence 
 input clk,rst                                   ;//system clock,reset
 

//-----------------------------------------output---------------------------------------------//

output  reg signed [WIDTH_OUT-1:0]seq_out       ;//output sequence



//------------------------------------------logic-------------------------------------------//


always@(posedge clk)begin
  if(!rst)begin
  
    accum1<=0                               ;//reset=0,all register becomes zero
    accum2<=0                               ;
    accum3<=0                               ;
    accum4<=0                               ;
    accum5<=0                               ;
    accum6<=0                               ;
    accum7<=0                               ;
    accum8<=0                               ;
    accum9<=0                               ;
    accum10<=0                              ;
 
    in1m1<=0                                ;
    in1m2<=0                                ;
 
    q1<=8'b00000000                         ;
    q2<=8'b00000000                         ;
    q3<=8'b00000000                         ;
    q4<=8'b00000000                         ;
    q5<=8'b00000000                         ;
    q6<=8'b00000000                         ;
    q7<=8'b00000000                         ;
    q8<=8'b00000000                         ;
    q9<=8'b00000000                         ;
    q10<=8'b00000000                        ;
 
    end  
 
    else 
 
    q1<=seq_in                              ;               
    q2<=q1                                  ;
    q3<=q2                                  ;
    q4<=q3                                  ;
    q5<=q4                                  ;
    q6<=q5                                  ; 
    q7<=q6                                  ;
    q8<=q7                                  ;
    q9<=q8                                  ; 
    q10<=q9                                 ;
    end


//----------------------------------------------state machine---------------------------------//

always@(posedge clk)begin 
case(state)
4'b0001:begin  
        in1m1<=q1        ;
        in2m1<=H1        ;
        accum1<=out_add  ;  
        state<=4'b0010   ;
        end
4'b0010:begin
        in1m1<=q2       ;
        in2m1<=H2       ;
        accum2<=out_add ;
        state<=4'b0011  ;
        end
4'b0011:begin
       in1m1<=q3        ;
       in2m1<=H3        ;
       accum3<=out_add  ;
       state<=4'b0100   ;
       end
4'b0100:begin
       in1m1<=q4        ;
       in2m1<=H4        ;
       accum4<=out_add  ;
       state<=4'b0101   ; 
       end
4'b0101:begin
        in1m1<= q5      ;
        in2m1<=H5       ;
        accum5<=out_add ;
        state<=4'b0110  ;
        end  
4'b0110:begin
        in1m1<= q6      ;
        in2m1<=H6       ;
        accum6<=out_add ;
        state<=4'b0111  ;
        end 
4'b0111:begin 
        in1m1<=q7        ;
        in2m1<=H7        ;
        accum7<=out_add  ;  
        state<=4'b1000   ;
        end
4'b1000:begin
        in1m1<=q8       ;
        in2m1<=H8       ;
        accum8<=out_add ;
        state<=4'b1001  ;
        end 
4'b1001:begin
        in1m1<=q9        ;
        in2m1<=H9        ;
        accum9<=out_add  ;
        state<=4'b1010   ;
        end
4'b1010:begin
        in1m1<= q10      ;
        in2m1<=H10       ;
        accum10<=out_add ;
        seq_out<=(accum1+accum2+accum3+accum4+accum5+accum6+accum7_accum8+accum9+accum10);//output calculated
        state<=4'b0000   ;
        end

//-------------------------------------------multipliers--------------------------------------//
 
multiplication   m1(.clk(clk  ), 
                .rst(rst),
                .input1(in1m1),
                .input2(in2m1),
                .output(out_add)
    );

endmodule




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