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module halfband_ideal (
input clock,
input reset,
input enable,
input strobe_in,
input wire signed [17:0] data_in,
output reg strobe_out,
output reg signed [17:0] data_out
) ;
parameter decim = 1 ;
parameter rate = 2 ;
reg signed [40:0] temp ;
reg signed [17:0] delay[30:0] ;
reg signed [17:0] coeffs[30:0] ;
reg [7:0] count ;
integer i ;
initial begin
for( i = 0 ; i < 31 ; i = i + 1 ) begin
coeffs[i] = 18'd0 ;
end
coeffs[0] = -1390 ;
coeffs[2] = 1604 ;
coeffs[4] = -1896 ;
coeffs[6] = 2317 ;
coeffs[8] = -2979 ;
coeffs[10] = 4172 ;
coeffs[12] = -6953 ;
coeffs[14] = 20860 ;
coeffs[15] = 32768 ;
coeffs[16] = 20860 ;
coeffs[18] = -6953 ;
coeffs[20] = 4172 ;
coeffs[22] = -2979 ;
coeffs[24] = 2317 ;
coeffs[26] = -1896 ;
coeffs[28] = 1604 ;
coeffs[30] = -1390 ;
end
always @(posedge clock) begin
if( reset ) begin
count <= 0 ;
for( i = 0 ; i < 31 ; i = i + 1 ) begin
delay[i] <= 18'd0 ;
end
temp <= 41'd0 ;
data_out <= 18'd0 ;
strobe_out <= 1'b0 ;
end else if( enable ) begin
if( (decim && (count == rate-1)) || !decim )
strobe_out <= strobe_in ;
else
strobe_out <= 1'b0 ;
if( strobe_in ) begin
// Increment decimation count
count <= count + 1 ;
// Shift the input
for( i = 30 ; i > 0 ; i = i - 1 ) begin
delay[i] = delay[i-1] ;
end
delay[0] = data_in ;
// clear the temp reg
temp = 18'd0 ;
if( (decim && (count == rate-1)) || !decim ) begin
count <= 0 ;
for( i = 0 ; i < 31 ; i = i + 1 ) begin
// Multiply Accumulate
temp = temp + delay[i]*coeffs[i] ;
end
// Assign data output
data_out <= temp >>> 15 ;
end
end
end
end
endmodule
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