def test_init(self): ant = antenna.AntennaRX(name='a rx', lat=2.43, lon=11.0, el_thresh=30.0, freq=1e4, rx_noise=10e3, beam=self.beam_u, alt=0.0)
def eiscat_uhf(): uhf_lat = 69.58649229 uhf_lon = 19.22592538 uhf_alt = 85.554 rx_beam = alib.uhf_beam(az0=90.0, el0=75.0, I_0=10**4.81, f=930e6) scan = rslib.beampark_model( az=90.0, el=75.0, lat=uhf_lat, lon=uhf_lon, alt=uhf_alt, ) uhf = antenna.AntennaRX( name="UHF Tromso", lat=uhf_lat, lon=uhf_lon, alt=uhf_alt, el_thresh=30, freq=930e6, rx_noise=100, beam=rx_beam, scan=scan, phased=False, ) tx_beam = alib.uhf_beam(az0=90.0, el0=75.0, I_0=10**4.81, f=930e6) uhf_tx = antenna.AntennaTX( name="UHF Tromso TX", lat=uhf_lat, lon=uhf_lon, alt=uhf_alt, el_thresh=30, freq=930e6, rx_noise=100, beam=tx_beam, scan=scan, tx_power=1.6e6, # 2 MW? tx_bandwidth=1e6, # 1 MHz duty_cycle=0.125, n_ipp=10.0, ipp=20e-3, pulse_length=30.0 * 64.0 * 1e-6, phased=False, ) # EISCAT UHF beampark tx = [uhf_tx] rx = [uhf] euhf = RadarSystem(tx, rx, 'Eiscat UHF') euhf.set_SNR_limits(14.0, 14.0) return euhf
def test_ecef(self): dec = 4 ant = antenna.AntennaRX(name='a rx', lat=0, lon=0, el_thresh=30.0, freq=1e4, rx_noise=10e3, beam=self.beam_u, alt=0.0) nt.assert_almost_equal(ant.ecef[0], coord.a, decimal=dec) ant = antenna.AntennaRX(name='a rx', lat=0, lon=0, el_thresh=30.0, freq=1e4, rx_noise=10e3, beam=self.beam_u, alt=100.0) nt.assert_almost_equal(ant.ecef[0], coord.a + 100, decimal=dec) ant = antenna.AntennaRX(name='a rx', lat=90, lon=0, el_thresh=30.0, freq=1e4, rx_noise=10e3, beam=self.beam_u, alt=0.0) nt.assert_almost_equal(ant.ecef[2], coord.b, decimal=dec) ant = antenna.AntennaRX(name='a rx', lat=0, lon=90, el_thresh=30.0, freq=1e4, rx_noise=10e3, beam=self.beam_u, alt=0.0) nt.assert_almost_equal(ant.ecef[1], coord.a, decimal=dec)
def setUp(self): self.beam_u = antenna.BeamPattern(lambda k, sf: sf.I_0, az0=0.0, el0=90.0, I_0=1.0, f=1.0, beam_name='Test') self.tx_lst = [] self.tx_lst.append( antenna.AntennaTX( name='a tx', lat=2.43, lon=11.0, alt=0.0, el_thresh=30.0, freq=1e4, rx_noise=10e3, beam=self.beam_u, scan=None, tx_power=1.0, tx_bandwidth=1.0, duty_cycle=1.0, )) self.tx_lst.append( antenna.AntennaTX( name='a tx', lat=2.43, lon=12.0, alt=0.0, el_thresh=30.0, freq=1e4, rx_noise=10e3, beam=self.beam_u, scan=None, tx_power=1.0, tx_bandwidth=1.0, duty_cycle=1.0, )) self.rx_lst = [] for of in range(10): self.tx_lst.append( antenna.AntennaRX(name='a rx', lat=2.43 + of, lon=11.0, alt=0.0, el_thresh=30.0, freq=1e4, rx_noise=10e3, beam=self.beam_u))
def tromso_space_radar(freq=1.2e9): lat = 69.5866115 lon = 19.221555 alt = 85.0 rx_beam = alib.tsr_beam( el0=90.0, f=freq, ) scan = rslib.beampark_model( az=0.0, el=90.0, lat=lat, lon=lon, alt=alt, ) tsr_rx = antenna.AntennaRX( name="Tromso Space Radar", lat=lat, lon=lon, alt=alt, el_thresh=30, freq=freq, rx_noise=100, beam=rx_beam, phased=False, scan=scan, ) tx_beam = alib.tsr_beam( el0=90.0, f=freq, ) tsr_tx = antenna.AntennaTX( name="Tromso Space Radar TX", lat=lat, lon=lon, alt=alt, el_thresh=30, freq=freq, rx_noise=100, beam=tx_beam, scan=scan, tx_power=500.0e3, tx_bandwidth=1e6, duty_cycle=0.125, n_ipp=10.0, ipp=20e-3, pulse_length=30.0 * 64.0 * 1e-6, ) # EISCAT UHF beampark tx = [tsr_tx] rx = [tsr_rx] tsr_r = RadarSystem(tx, rx, 'Tromso Space Radar') tsr_r.set_SNR_limits(10.0, 10.0) return tsr_r
def eiscat_svalbard(): """ The steerable antenna of the ESR radar, default settings for the Space Debris radar mode. """ uhf_lat = 78.15 uhf_lon = 16.02 uhf_alt = 0.0 rx_beam = alib.uhf_beam( az0=90.0, el0=75.0, I_0=10**4.25, f=500e6, ) tx_beam = alib.uhf_beam( az0=90.0, el0=75.0, I_0=10**4.25, f=500e6, ) scan = rslib.beampark_model( az=90.0, el=75.0, lat=uhf_lat, lon=uhf_lon, alt=uhf_alt, ) uhf = antenna.AntennaRX( name="Steerable Svalbard", lat=uhf_lat, lon=uhf_lon, alt=uhf_alt, el_thresh=30, freq=500e6, rx_noise=120, beam=rx_beam, phased=False, scan=scan, ) uhf_tx = antenna.AntennaTX( name="Steerable Svalbard TX", lat=uhf_lat, lon=uhf_lon, alt=uhf_alt, el_thresh=30, freq=500e6, rx_noise=120, beam=tx_beam, scan=scan, tx_power=0.6e6, # 600 kW tx_bandwidth=1e6, # 1 MHz duty_cycle=0.125, pulse_length=30.0 * 64.0 * 1e-6, ipp=20e-3, n_ipp=10.0, ) # EISCAT UHF beampark tx = [uhf_tx] rx = [uhf] euhf = RadarSystem(tx, rx, 'Eiscat Svalbard Steerable Antenna') euhf.set_SNR_limits(14.77, 14.77) return euhf
def eiscat_3d(beam='interp', stage=1): '''The EISCAT_3D system. For more information see: * `EISCAT <https://eiscat.se/>`_ * `EISCAT 3D <https://www.eiscat.se/eiscat3d/>`_ :param str beam: Decides what initial antenna radiation-model to use. :param int stage: The stage of development of EISCAT 3D. **EISCAT 3D Stages:** * Stage 1: As of writing it is assumed to have all of the antennas in place but only transmitters on half of the antennas in a dense core ,i.e. TX will have 42 dB peak gain while RX still has 45 dB peak gain. 3 Sites will exist, one is a TX and RX, the other 2 RX sites. * Stage 2: Both TX and RX sites will have 45 dB peak gain. * Stage 3: (NOT IMPLEMENTED HERE) 2 additional RX sites will be added. **Beam options:** * gauss: Gaussian tapered beam model :func:`antenna_library.planar_beam`. * interp: Interpolated array pattern. * array: Ideal summation of all antennas in the array :func:`antenna_library.e3d_array_beam_stage1` and :func:`antenna_library.e3d_array_beam`. # TODO: Geographical location measured with? Probably WGS84. ''' e3d_freq = 233e6 if stage == 1: e3d_tx_gain = 10**4.3 a0_tx = 20.0 elif stage == 2: e3d_tx_gain = 10**4.5 a0_tx = 40.0 else: raise Exception('Stage "{}" not recognized.'.format(stage)) e3d_rx_gain = 10**4.5 if beam == 'gauss': tx_beam_ski = alib.planar_beam( az0=0, el0=90, I_0=e3d_tx_gain, f=e3d_freq, a0=a0_tx, az1=0.0, el1=90.0, ) rx_beam_ski = alib.planar_beam( az0=0, el0=90, I_0=e3d_rx_gain, f=e3d_freq, a0=40.0, az1=0.0, el1=90.0, ) rx_beam_kar = alib.planar_beam( az0=0, el0=90, I_0=e3d_rx_gain, f=e3d_freq, a0=40.0, az1=0.0, el1=90.0, ) rx_beam_kai = alib.planar_beam( az0=0, el0=90, I_0=e3d_rx_gain, f=e3d_freq, a0=40.0, az1=0.0, el1=90.0, ) elif beam == 'array': if stage == 1: tx_beam_ski = alib.e3d_array_beam_stage1( az0=0, el0=90, I_0=e3d_tx_gain, opt='dense', ) elif stage == 2: tx_beam_ski = alib.e3d_array_beam( az0=0, el0=90, I_0=e3d_tx_gain, ) rx_beam_ski = alib.e3d_array_beam( az0=0, el0=90, I_0=e3d_rx_gain, ) rx_beam_kar = alib.e3d_array_beam( az0=0, el0=90, I_0=e3d_rx_gain, ) rx_beam_kai = alib.e3d_array_beam( az0=0, el0=90, I_0=e3d_rx_gain, ) elif beam == 'interp': if stage == 1: tx_beam_ski = alib.e3d_array_beam_stage1_dense_interp( az0=0, el0=90, I_0=e3d_tx_gain, ) elif stage == 2: tx_beam_ski = alib.e3d_array_beam_interp( az0=0, el0=90, I_0=e3d_tx_gain, ) rx_beam_ski = alib.e3d_array_beam_interp( az0=0, el0=90, I_0=e3d_rx_gain, ) rx_beam_kar = alib.e3d_array_beam_interp( az0=0, el0=90, I_0=e3d_rx_gain, ) rx_beam_kai = alib.e3d_array_beam_interp( az0=0, el0=90, I_0=e3d_rx_gain, ) else: raise Exception('Beam model "{}" not recognized.'.format(beam)) ski_lat = 69.34023844 ski_lon = 20.313166 ski_alt = 0.0 ski = antenna.AntennaRX( name="Skibotn", lat=ski_lat, lon=ski_lon, alt=ski_alt, el_thresh=30, freq=e3d_freq, rx_noise=150, beam=rx_beam_ski, ) dwell_time = 0.1 scan = rslib.ew_fence_model( lat=ski_lat, lon=ski_lon, alt=ski_alt, min_el=30, angle_step=1.0, dwell_time=dwell_time, ) ski_tx = antenna.AntennaTX( name="Skibotn TX", lat=ski_lat, lon=ski_lon, alt=ski_alt, el_thresh=30, freq=e3d_freq, rx_noise=150, beam=tx_beam_ski, scan=scan, tx_power=5e6, # 5 MW tx_bandwidth=100e3, # 100 kHz tx bandwidth duty_cycle=0.25, # 25% duty-cycle pulse_length=1920e-6, ipp=10e-3, n_ipp=int(dwell_time / 10e-3), ) kar_lat = 68.463862 kar_lon = 22.458859 kar_alt = 0.0 kar = antenna.AntennaRX( name="Karesuvanto", lat=kar_lat, lon=kar_lon, alt=kar_alt, el_thresh=30, freq=e3d_freq, rx_noise=150, beam=rx_beam_kar, ) kai_lat = 68.148205 kai_lon = 19.769894 kai_alt = 0.0 kai = antenna.AntennaRX( name="Kaiseniemi", lat=kai_lat, lon=kai_lon, alt=kai_alt, el_thresh=30, freq=e3d_freq, rx_noise=150, beam=rx_beam_kai, ) # define transmit and receive antennas for a radar network. tx = [ski_tx] rx = [ski, kar, kai] if stage > 1: name = 'EISCAT 3D stage {}'.format(stage) else: name = 'EISCAT 3D' e3d = RadarSystem( tx_lst=tx, rx_lst=rx, name=name, max_on_axis=15.0, min_SNRdb=1.0, ) e3d.set_SNR_limits(10.0, 10.0) return e3d
def mock_radar(): lat = 90.0 lon = 0.0 alt = 0.0 rx_beam = alib.planar_beam( az0=0, el0=90, I_0=10**4.5, f=233e6, a0=40, az1=0.0, el1=90.0, ) tx_beam = alib.planar_beam( az0=0, el0=90, I_0=10**4.5, f=233e6, a0=40, az1=0.0, el1=90.0, ) rx = antenna.AntennaRX( name="Top", lat=lat, lon=lon, alt=alt, el_thresh=30, freq=233e6, rx_noise=120, beam=rx_beam, ) scan = rslib.beampark_model( az=0.0, el=90.0, lat=lat, lon=lon, alt=alt, ) tx = antenna.AntennaTX( name="Top TX", lat=lat, lon=lon, alt=alt, el_thresh=30, freq=233e6, rx_noise=120, beam=tx_beam, scan=scan, tx_power=5.0e6, tx_bandwidth=1e6, # 1 MHz duty_cycle=0.25, pulse_length=30.0 * 64.0 * 1e-6, ipp=20e-3, n_ipp=10.0, ) tx = [tx] rx = [rx] Mock = RadarSystem(tx, rx, 'Mock radar') Mock.set_FOV(max_on_axis=90.0, horizon_elevation=0.0) return Mock
def mock_radar_mult(): lat = [85.0, 89.0, 90.0, 89.0, 85.0] lon = [0, 90.0, 0, 270.0, 180] alt = 0.0 tx_l = [] rx_l = [] for ind in range(5): rx_beam = alib.planar_beam( az0=0, el0=90, I_0=10**4.5, f=233e6, a0=40, az1=0.0, el1=90.0, ) rx = antenna.AntennaRX( name="Top", lat=lat[ind], lon=lon[ind], alt=alt, el_thresh=30, freq=233e6, rx_noise=120, beam=rx_beam, ) rx_l.append(rx) lat = [90.0, 87.0] lon = [0, 0.0] for ind in range(2): tx_beam = alib.planar_beam( az0=0, el0=90, I_0=10**4.5, f=233e6, a0=40, az1=0.0, el1=90.0, ) scan = rslib.beampark_model( az=0.0, el=90.0, lat=lat[ind], lon=lon[ind], alt=alt, ) tx = antenna.AntennaTX( name="Top TX", lat=lat[ind], lon=lon[ind], alt=alt, el_thresh=30, freq=233e6, rx_noise=120, beam=tx_beam, scan=scan, tx_power=5.0e6, tx_bandwidth=1e6, # 1 MHz duty_cycle=0.25, pulse_length=30.0 * 64.0 * 1e-6, ipp=20e-3, n_ipp=10.0, ) tx_l.append(tx) Mock = RadarSystem(tx_l, rx_l, 'bIG Mock radar') Mock.set_FOV(max_on_axis=90.0, horizon_elevation=0.0) return Mock