subroutine ft2_gfsk_iwave(msg37,f0,snrdb,iwave) ! Generate waveform for experimental "FT2" mode use packjt77 include 'ft2_params.f90' !Set various constants parameter (NWAVE=(NN+2)*NSPS) character msg37*37,msgsent37*37 real wave(NWAVE),xnoise(NWAVE) real dphi(NWAVE) real pulse(480) integer itone(NN) integer*2 iwave(NWAVE) !Generated full-length waveform logical first data first/.true./ save pulse twopi=8.0*atan(1.0) fs=12000.0 !Sample rate (Hz) dt=1.0/fs !Sample interval (s) hmod=0.8 !Modulation index (MSK=0.5, FSK=1.0) tt=NSPS*dt !Duration of symbols (s) baud=1.0/tt !Keying rate (baud) bw=1.5*baud !Occupied bandwidth (Hz) txt=NZ*dt !Transmission length (s) bandwidth_ratio=2500.0/(fs/2.0) ! sig=sqrt(2*bandwidth_ratio) * 10.0**(0.05*snrdb) ! if(snrdb.gt.90.0) sig=1.0 txt=NN*NSPS/12000.0 if(first) then ! The filtered frequency pulse do i=1,480 tt=(i-240.5)/160.0 pulse(i)=gfsk_pulse(1.0,tt) enddo dphi_peak=twopi*(hmod/2.0)/real(NSPS) first=.false. endif ! Source-encode, then get itone(): itype=1 call genft2(msg37,0,msgsent37,itone,itype) ! Create the instantaneous frequency waveform dphi=0.0 do j=1,NN ib=(j-1)*160+1 ie=ib+480-1 dphi(ib:ie)=dphi(ib:ie)+dphi_peak*pulse*(2*itone(j)-1) enddo phi=0.0 wave=0.0 sqrt2=sqrt(2.) dphi=dphi+twopi*f0*dt do j=1,NWAVE wave(j)=sqrt2*sin(phi) sqsig=sqsig + wave(j)**2 phi=mod(phi+dphi(j),twopi) enddo wave(1:160)=wave(1:160)*(1.0-cos(twopi*(/(i,i=0,159)/)/320.0) )/2.0 wave(145*160+1:146*160)=wave(145*160+1:146*160)*(1.0+cos(twopi*(/(i,i=0,159)/)/320.0 ))/2.0 wave(146*160+1:)=0. if(snrdb.gt.90.0) then iwave=nint((32767.0/sqrt(2.0))*wave) return endif sqnoise=1.e-30 if(snrdb.lt.90) then do i=1,NWAVE !Add gaussian noise at specified SNR xnoise(i)=gran() !Noise has rms = 1.0 enddo endif xnoise=xnoise*sqrt(0.5*fs/2500.0) fac=30.0 snr_amplitude=10.0**(0.05*snrdb) wave=fac*(snr_amplitude*wave + xnoise) datpk=maxval(abs(wave)) print*,'A',snr_amplitude,datpk iwave=nint((30000.0/datpk)*wave) return end subroutine ft2_gfsk_iwave