Exemplo n.º 1
0
 def func_fuel(self, x, mass):
     mach, h = denormalize(x, self.normfactor)
     va = aero.mach2tas(mach, h)
     ff = self.fuelflow.enroute(mass, va / aero.kts, h / aero.ft)
     ff_m = ff / (va + 1e-3) * 1000
     # print("%.03f" % mach, "%d" % (h/aero.ft), "%.05f" % ff_m)
     return ff_m
Exemplo n.º 2
0
    def func_cons_thrust(self, x, mass):
        mach, h = denormalize(x, self.normfactor)
        va = aero.mach2tas(mach, h)

        D = self.drag.clean(mass, va / aero.kts, h / aero.ft)
        Tmax = self.thrust.cruise(va / aero.kts, h / aero.ft)

        dT = Tmax - D
        return dT
Exemplo n.º 3
0
    def func_cons_lift(self, x, mass):
        mach, h = denormalize(x, self.normfactor)
        va = aero.mach2tas(mach, h)

        Tmax = self.thrust.cruise(va / aero.kts, h / aero.ft)

        qS = 0.5 * aero.density(h) * va**2 * self.aircraft['wing']['area']
        cd0 = self.drag.polar['clean']['cd0']
        k = self.drag.polar['clean']['k']

        mach_crit = self.drag.polar['mach_crit']
        if mach > mach_crit:
            cd0 += 20 * (mach - mach_crit)**4

        dL2 = qS**2 * (1 / k * (Tmax /
                                (qS + 1e-3) - cd0)) - (mass * aero.g0)**2
        return dL2
Exemplo n.º 4
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 def func_time(self, x, mass):
     mach, h = denormalize(x, self.normfactor)
     va = aero.mach2tas(mach, h)
     va_inv = 1 / (va + 1e-4) * 1000
     # print("%.03f" % mach, "%d" % (h/aero.ft), "%.02f" % va)
     return va_inv
Exemplo n.º 5
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    def climb(self, **kwargs):
        """Generate climb trajectory based on WRAP model.

        Args:
            **dt (int): Time step in seconds.
            **cas_const_cl (int): Constaant CAS for climb (kt).
            **mach_const_cl (float): Constaant Mach for climb (-).
            **h_cr (int): Target cruise altitude (km).
            **random (bool): Generate trajectory with random paramerters.

        Returns:
            dict: Flight trajectory.

        """
        dt = kwargs.get('dt', 1)
        random = kwargs.get('random', False)

        a_tof = self.wrap.takeoff_acceleration()['default']
        v_tof = self.wrap.takeoff_speed()['default']

        if random:
            cas_const = kwargs.get(
                'cas_const_cl',
                np.random.uniform(self.wrap.climb_const_vcas()['minimum'],
                                  self.wrap.climb_const_vcas()['maximum']) /
                aero.kts)

            mach_const = kwargs.get(
                'mach_const_cl',
                np.random.uniform(self.wrap.climb_const_mach()['minimum'],
                                  self.wrap.climb_const_mach()['maximum']))

            h_cr = kwargs.get(
                'h_cr',
                np.random.uniform(self.wrap.cruise_alt()['minimum'],
                                  self.wrap.cruise_alt()['maximum']) * 1000)

            vs_pre_constcas = np.random.uniform(
                self.wrap.climb_vs_pre_concas()['minimum'],
                self.wrap.climb_vs_pre_concas()['maximum'])

            vs_constcas = np.random.uniform(
                self.wrap.climb_vs_concas()['minimum'],
                self.wrap.climb_vs_concas()['maximum'])

            vs_constmach = np.random.uniform(
                self.wrap.climb_vs_conmach()['minimum'],
                self.wrap.climb_vs_conmach()['maximum'])

        else:
            cas_const = kwargs.get(
                'cas_const_cl',
                self.wrap.climb_const_vcas()['default'] / aero.kts)
            mach_const = kwargs.get('mach_const_cl',
                                    self.wrap.climb_const_mach()['default'])
            h_cr = kwargs.get('h_cr', self.wrap.cruise_alt()['default'] * 1000)
            vs_pre_constcas = self.wrap.climb_vs_pre_concas()['default']
            vs_constcas = self.wrap.climb_vs_concas()['default']
            vs_constmach = self.wrap.climb_vs_conmach()['default']

        vcas_const = cas_const * aero.kts
        h_cr = np.round(h_cr / aero.ft,
                        -2) * aero.ft  # round cruise altitude to flight level
        vs_ic = self.wrap.initclimb_vs()['default']
        h_const_cas = self.wrap.climb_cross_alt_concas()['default'] * 1000

        h_const_mach = aero.crossover_alt(vcas_const, mach_const)
        if h_const_mach > h_cr:
            print(
                'Warining: const mach crossover altitude higher than cruise altitude, altitude clipped.'
            )

        data = []

        # intitial conditions
        t = 0
        tcr = 0
        h = 0
        s = 0
        v = 0
        vs = 0
        a = 0.5  # standard acceleration m/s^2
        seg = None

        while True:
            data.append([t, h, s, v, vs, seg])
            t = t + dt
            s = s + v * dt
            h = h + vs * dt

            if v < v_tof:
                v = v + a_tof * dt
                vs = 0
                seg = 'TO'
            elif h < 1500 * aero.ft:
                v = v + a * dt
                vs = vs_ic
                seg = 'IC'
            elif h < h_const_cas:
                v = v + a * dt
                if aero.tas2cas(v, h) >= vcas_const:
                    v = aero.cas2tas(vcas_const, h)
                vs = vs_pre_constcas
                seg = 'PRE-CAS'
            elif h < h_const_mach:
                v = aero.cas2tas(vcas_const, h)
                vs = vs_constcas
                seg = 'CAS'
            elif h < h_cr:
                v = aero.mach2tas(mach_const, h)
                vs = vs_constmach
                seg = 'MACH'
            else:
                v = aero.mach2tas(mach_const, h)
                vs = 0
                seg = 'CR'
                if tcr == 0:
                    tcr = t
                if t - tcr > 60:
                    break

        data = np.array(data)
        ndata = len(data)
        datadict = {
            't': data[:, 0],
            'h': data[:, 1] + np.random.normal(0, self.sigma_h, ndata),
            's': data[:, 2] + np.random.normal(0, self.sigma_s, ndata),
            'v': data[:, 3] + np.random.normal(0, self.sigma_v, ndata),
            'vs': data[:, 4] + np.random.normal(0, self.sigma_vs, ndata),
            'seg': data[:, 5],
            'cas_const_cl': cas_const,
            'mach_const_cl': mach_const,
            'h_cr': h_cr
        }

        return datadict
Exemplo n.º 6
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    def cruise(self, **kwargs):
        """Generate descent trajectory based on WRAP model.

        Args:
            **dt (int): Time step in seconds.
            **range_cr (int): Cruise range (km).
            **h_cr (int): Cruise altitude (km).
            **mach_cr (float): Cruise Mach number (-).
            **random (bool): Generate trajectory with random paramerters.

        Returns:
            dict: flight trajectory

        """
        dt = kwargs.get('dt', 1)
        random = kwargs.get('random', False)

        if random:
            range = kwargs.get(
                'range_cr',
                np.random.uniform(self.wrap.cruise_range()['minimum'],
                                  self.wrap.cruise_range()['maximum']) * 1000)

            h_cr = kwargs.get(
                'h_cr',
                np.random.uniform(self.wrap.cruise_alt()['minimum'],
                                  self.wrap.cruise_alt()['maximum']) * 1000)

            mach_cr = kwargs.get(
                'mach_cr',
                np.random.uniform(self.wrap.cruise_mach()['minimum'],
                                  self.wrap.cruise_mach()['maximum']))
        else:
            range = kwargs.get('range_cr',
                               self.wrap.cruise_range()['default'] * 1000)
            mach_cr = kwargs.get('mach_cr', self.wrap.cruise_mach()['default'])
            h_cr = kwargs.get('h_cr', self.wrap.cruise_alt()['default'] * 1000)

        h_cr = np.round(h_cr / aero.ft,
                        -3) * aero.ft  # round cruise altitude to flight level

        data = []

        # intitial conditions
        t = 0
        s = 0
        v = aero.mach2tas(mach_cr, h_cr)
        vs = 0

        while True:
            data.append([t, h_cr, s, v, vs])
            t = t + dt
            s = s + v * dt

            if s > range:
                break

        data = np.array(data)
        ndata = len(data)
        datadict = {
            't': data[:, 0],
            'h': data[:, 1] + np.random.normal(0, self.sigma_h, ndata),
            's': data[:, 2] + np.random.normal(0, self.sigma_s, ndata),
            'v': data[:, 3] + np.random.normal(0, self.sigma_v, ndata),
            'vs': data[:, 4] + np.random.normal(0, self.sigma_vs, ndata),
            'h_cr': h_cr,
            'mach_cr': mach_cr,
        }

        return datadict
Exemplo n.º 7
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    def descent(self, **kwargs):
        """Generate descent trajectory based on WRAP model.

        Args:
            **dt (int): Time step in seconds.
            **cas_const_de (int): Constaant CAS for climb (kt).
            **mach_const_de (float): Constaant Mach for climb (-).
            **h_cr (int): Target cruise altitude (km).
            **random (bool): Generate trajectory with random paramerters.

        Returns:
            dict: Flight trajectory.

        """
        dt = kwargs.get('dt', 1)
        random = kwargs.get('random', False)

        a_lnd = self.wrap.landing_acceleration()['default']
        v_app = self.wrap.finalapp_vcas()['default']

        if random:
            h_cr = kwargs.get(
                'h_cr',
                np.random.uniform(self.wrap.cruise_alt()['minimum'],
                                  self.wrap.cruise_alt()['maximum']) * 1000)

            mach_const = kwargs.get(
                'mach_const_de',
                np.random.uniform(self.wrap.descent_const_mach()['minimum'],
                                  self.wrap.descent_const_mach()['maximum']))

            cas_const = kwargs.get(
                'cas_const_de',
                np.random.uniform(self.wrap.descent_const_vcas()['minimum'],
                                  self.wrap.descent_const_vcas()['maximum']) /
                aero.kts)

            vs_constmach = np.random.uniform(
                self.wrap.descent_vs_conmach()['minimum'],
                self.wrap.descent_vs_conmach()['maximum'])

            vs_constcas = np.random.uniform(
                self.wrap.descent_vs_concas()['minimum'],
                self.wrap.descent_vs_concas()['maximum'])

            vs_post_constcas = np.random.uniform(
                self.wrap.descent_vs_post_concas()['minimum'],
                self.wrap.descent_vs_post_concas()['maximum'])

        else:
            mach_const = kwargs.get('mach_const_de',
                                    self.wrap.descent_const_mach()['default'])
            cas_const = kwargs.get(
                'cas_const_de',
                self.wrap.descent_const_vcas()['default'] / aero.kts)
            h_cr = kwargs.get('h_cr', self.wrap.cruise_alt()['default'] * 1000)
            vs_constmach = self.wrap.descent_vs_conmach()['default']
            vs_constcas = self.wrap.descent_vs_concas()['default']
            vs_post_constcas = self.wrap.descent_vs_post_concas()['default']

        vcas_const = cas_const * aero.kts
        h_cr = np.round(h_cr / aero.ft,
                        -2) * aero.ft  # round cruise altitude to flight level
        vs_fa = self.wrap.finalapp_vs()['default']
        h_const_cas = self.wrap.descent_cross_alt_concas()['default'] * 1000

        h_const_mach = aero.crossover_alt(vcas_const, mach_const)
        if h_const_mach > h_cr:
            print(
                'Warining: const mach crossover altitude higher than cruise altitude, altitude clipped.'
            )

        data = []

        # intitial conditions
        a = -0.5
        t = 0
        s = 0
        h = h_cr
        v = aero.mach2tas(mach_const, h_cr)
        vs = 0
        seg = None

        while True:
            data.append([t, h, s, v, vs, seg])
            t = t + dt
            s = s + v * dt
            h = h + vs * dt

            if t < 60:
                v = aero.mach2tas(mach_const, h)
                vs = 0
                seg = 'CR'
            elif h > h_const_mach:
                v = aero.mach2tas(mach_const, h)
                vs = vs_constmach
                seg = 'MACH'
            elif h > h_const_cas:
                v = aero.cas2tas(vcas_const, h)
                vs = vs_constcas
                seg = 'CAS'
            elif h > 1000 * aero.ft:
                v = v + a * dt
                if aero.tas2cas(v, h) < v_app:
                    v = aero.cas2tas(v_app, h)
                vs = vs_post_constcas
                seg = 'POST-CAS'
            elif h > 0:
                v = v_app
                vs = vs_fa
                seg = 'FA'
            else:
                h = 0
                vs = 0
                v = v + a_lnd * dt
                seg = 'LD'

                if v <= 0:
                    break

        data = np.array(data)
        ndata = len(data)
        datadict = {
            't': data[:, 0],
            'h': data[:, 1] + np.random.normal(0, self.sigma_h, ndata),
            's': data[:, 2] + np.random.normal(0, self.sigma_s, ndata),
            'v': data[:, 3] + np.random.normal(0, self.sigma_v, ndata),
            'vs': data[:, 4] + np.random.normal(0, self.sigma_vs, ndata),
            'seg': data[:, 5],
            'cas_const_de': cas_const,
            'vcas_const_de': vcas_const,
            'mach_const_de': mach_const,
            'h_cr': h_cr
        }

        return datadict
Exemplo n.º 8
0
    def climb(self, **kwargs):
        """Generate climb trajectory based on WRAP model.

        Args:
            **dt (int): Time step in seconds.
            **cas_const_cl (int): Constaant CAS for climb (kt).
            **mach_const_cl (float): Constaant Mach for climb (-).
            **alt_cr (int): Target cruise altitude (ft).
            **random (bool): Generate trajectory with random paramerters.

        Returns:
            dict: Flight trajectory.

        """
        dt = kwargs.get("dt", 1)
        random = kwargs.get("random", False)

        a_tof = self.wrap.takeoff_acceleration()["default"]
        v_tof = self.wrap.takeoff_speed()["default"]

        if random:
            cas_const = kwargs.get(
                "cas_const_cl",
                np.random.uniform(
                    self.wrap.climb_const_vcas()["minimum"],
                    self.wrap.climb_const_vcas()["maximum"],
                ) / aero.kts,
            )

            mach_const = kwargs.get(
                "mach_const_cl",
                np.random.uniform(
                    self.wrap.climb_const_mach()["minimum"],
                    self.wrap.climb_const_mach()["maximum"],
                ),
            )

            alt_cr = kwargs.get(
                "alt_cr",
                np.random.uniform(self.wrap.cruise_alt()["minimum"],
                                  self.wrap.cruise_alt()["maximum"]) * 1000 /
                aero.ft,
            )

            vs_pre_constcas = np.random.uniform(
                self.wrap.climb_vs_pre_concas()["minimum"],
                self.wrap.climb_vs_pre_concas()["maximum"],
            )

            vs_constcas = np.random.uniform(
                self.wrap.climb_vs_concas()["minimum"],
                self.wrap.climb_vs_concas()["maximum"],
            )

            vs_constmach = np.random.uniform(
                self.wrap.climb_vs_conmach()["minimum"],
                self.wrap.climb_vs_conmach()["maximum"],
            )

        else:
            cas_const = kwargs.get(
                "cas_const_cl",
                self.wrap.climb_const_vcas()["default"] / aero.kts)
            cas_const = max(
                cas_const,
                v_tof / aero.kts)  # cas can not be smaller then takeoff speed
            mach_const = kwargs.get("mach_const_cl",
                                    self.wrap.climb_const_mach()["default"])
            alt_cr = kwargs.get(
                "alt_cr",
                self.wrap.cruise_alt()["default"] * 1000 / aero.ft)
            vs_pre_constcas = self.wrap.climb_vs_pre_concas()["default"]
            vs_constcas = self.wrap.climb_vs_concas()["default"]
            vs_constmach = self.wrap.climb_vs_conmach()["default"]

        vcas_const = cas_const * aero.kts
        alt_cr = np.round(alt_cr, -2)  # round cruise altitude to flight level
        h_cr = alt_cr * aero.ft  # meters
        vs_ic = self.wrap.initclimb_vs()["default"]
        h_const_cas = self.wrap.climb_cross_alt_concas()["default"] * 1000

        h_const_mach = aero.crossover_alt(vcas_const, mach_const)
        if h_const_mach > h_cr:
            print(
                "Warining: const mach crossover altitude higher than cruise altitude, altitude clipped."
            )

        data = []

        # intitial conditions
        t = 0
        tcr = 0
        h = 0
        s = 0
        v = 0
        vs = 0
        a = 0.5  # standard acceleration m/s^2
        seg = None

        while True:
            data.append([t, h, s, v, vs, seg])
            t = t + dt
            s = s + v * dt
            h = h + vs * dt

            if v < v_tof:
                v = v + a_tof * dt
                vs = 0
                seg = "TO"
            elif h < 1500 * aero.ft:
                v = v + a * dt
                if aero.tas2cas(v, h) >= vcas_const:
                    v = aero.cas2tas(vcas_const, h)
                vs = vs_ic
                seg = "IC"
            elif h < h_const_cas:
                v = v + a * dt
                if aero.tas2cas(v, h) >= vcas_const:
                    v = aero.cas2tas(vcas_const, h)
                vs = vs_pre_constcas
                seg = "PRE-CAS"
            elif h < h_const_mach:
                v = aero.cas2tas(vcas_const, h)
                vs = vs_constcas
                seg = "CAS"
            elif h < h_cr:
                v = aero.mach2tas(mach_const, h)
                vs = vs_constmach
                seg = "MACH"
            else:
                v = aero.mach2tas(mach_const, h)
                vs = 0
                seg = "CR"
                if tcr == 0:
                    tcr = t
                if t - tcr > 60:
                    break

        data = np.array(data)
        ndata = len(data)
        datadict = {
            "t": data[:, 0],  # t, seconds
            "h": data[:, 1] + np.random.normal(0, self.sigma_h, ndata),  # h, m
            "s": data[:, 2] + np.random.normal(0, self.sigma_s, ndata),  # s, m
            "v":
            data[:, 3] + np.random.normal(0, self.sigma_v, ndata),  # v, m/s
            "vs":
            data[:, 4] + np.random.normal(0, self.sigma_vs, ndata),  # VS, m/s
            "seg": data[:, 5],
            "cas_const_cl": cas_const,
            "mach_const_cl": mach_const,
            "alt_cr": alt_cr,  # alt_cr, ft
        }

        return datadict
Exemplo n.º 9
0
    def cruise(self, **kwargs):
        """Generate descent trajectory based on WRAP model.

        Args:
            **dt (int): Time step in seconds.
            **range_cr (int): Cruise range (km).
            **alt_cr (int): Cruise altitude (ft).
            **mach_cr (float): Cruise Mach number (-).
            **random (bool): Generate trajectory with random paramerters.

        Returns:
            dict: flight trajectory

        """
        dt = kwargs.get("dt", 1)
        random = kwargs.get("random", False)

        if random:
            range = kwargs.get(
                "range_cr",
                np.random.uniform(
                    self.wrap.cruise_range()["minimum"],
                    self.wrap.cruise_range()["maximum"],
                ) * 1000,
            )

            alt_cr = kwargs.get(
                "alt_cr",
                np.random.uniform(self.wrap.cruise_alt()["minimum"],
                                  self.wrap.cruise_alt()["maximum"]) * 1000 /
                aero.ft,
            )

            mach_cr = kwargs.get(
                "mach_cr",
                np.random.uniform(
                    self.wrap.cruise_mach()["minimum"],
                    self.wrap.cruise_mach()["maximum"],
                ),
            )
        else:
            range = kwargs.get("range_cr",
                               self.wrap.cruise_range()["default"] * 1000)
            mach_cr = kwargs.get("mach_cr", self.wrap.cruise_mach()["default"])
            alt_cr = kwargs.get(
                "alt_cr",
                self.wrap.cruise_alt()["default"] * 1000 / aero.ft)

        alt_cr = np.round(alt_cr, -2)  # round cruise altitude to flight level
        h_cr = alt_cr * aero.ft

        data = []

        # intitial conditions
        t = 0
        s = 0
        v = aero.mach2tas(mach_cr, h_cr)
        vs = 0

        while True:
            data.append([t, h_cr, s, v, vs])
            t = t + dt
            s = s + v * dt

            if s > range:
                break

        data = np.array(data)
        ndata = len(data)
        datadict = {
            "t": data[:, 0],
            "h": data[:, 1] + np.random.normal(0, self.sigma_h, ndata),
            "s": data[:, 2] + np.random.normal(0, self.sigma_s, ndata),
            "v": data[:, 3] + np.random.normal(0, self.sigma_v, ndata),
            "vs": data[:, 4] + np.random.normal(0, self.sigma_vs, ndata),
            "alt_cr": alt_cr,
            "mach_cr": mach_cr,
        }

        return datadict
Exemplo n.º 10
0
    def descent(self, **kwargs):
        """Generate descent trajectory based on WRAP model.

        Args:
            **dt (int): Time step in seconds.
            **cas_const_de (int): Constaant CAS for climb (kt).
            **mach_const_de (float): Constaant Mach for climb (-).
            **alt_cr (int): Target cruise altitude (ft).
            **random (bool): Generate trajectory with random paramerters.

        Returns:
            dict: Flight trajectory.

        """
        dt = kwargs.get("dt", 1)
        random = kwargs.get("random", False)

        a_lnd = self.wrap.landing_acceleration()["default"]
        v_app = self.wrap.finalapp_vcas()["default"]

        if random:
            alt_cr = kwargs.get(
                "alt_cr",
                np.random.uniform(self.wrap.cruise_alt()["minimum"],
                                  self.wrap.cruise_alt()["maximum"]) * 1000 /
                aero.ft,
            )

            mach_const = kwargs.get(
                "mach_const_de",
                np.random.uniform(
                    self.wrap.descent_const_mach()["minimum"],
                    self.wrap.descent_const_mach()["maximum"],
                ),
            )

            cas_const = kwargs.get(
                "cas_const_de",
                np.random.uniform(
                    self.wrap.descent_const_vcas()["minimum"],
                    self.wrap.descent_const_vcas()["maximum"],
                ) / aero.kts,
            )

            vs_constmach = np.random.uniform(
                self.wrap.descent_vs_conmach()["minimum"],
                self.wrap.descent_vs_conmach()["maximum"],
            )

            vs_constcas = np.random.uniform(
                self.wrap.descent_vs_concas()["minimum"],
                self.wrap.descent_vs_concas()["maximum"],
            )

            vs_post_constcas = np.random.uniform(
                self.wrap.descent_vs_post_concas()["minimum"],
                self.wrap.descent_vs_post_concas()["maximum"],
            )

        else:
            mach_const = kwargs.get("mach_const_de",
                                    self.wrap.descent_const_mach()["default"])
            cas_const = kwargs.get(
                "cas_const_de",
                self.wrap.descent_const_vcas()["default"] / aero.kts)
            alt_cr = kwargs.get(
                "alt_cr",
                self.wrap.cruise_alt()["default"] * 1000 / aero.ft)
            vs_constmach = self.wrap.descent_vs_conmach()["default"]
            vs_constcas = self.wrap.descent_vs_concas()["default"]
            vs_post_constcas = self.wrap.descent_vs_post_concas()["default"]

        vcas_const = cas_const * aero.kts
        alt_cr = np.round(alt_cr, -2)  # round cruise altitude to flight level
        h_cr = alt_cr * aero.ft
        vs_fa = self.wrap.finalapp_vs()["default"]
        h_const_cas = self.wrap.descent_cross_alt_concas()["default"] * 1000

        h_const_mach = aero.crossover_alt(vcas_const, mach_const)
        if h_const_mach > h_cr:
            print(
                "Warining: const mach crossover altitude higher than cruise altitude, altitude clipped."
            )

        data = []

        # intitial conditions
        a = -0.5
        t = 0
        s = 0
        h = h_cr
        v = aero.mach2tas(mach_const, h_cr)
        vs = 0
        seg = None

        while True:
            data.append([t, h, s, v, vs, seg])
            t = t + dt
            s = s + v * dt
            h = h + vs * dt

            if t < 60:
                v = aero.mach2tas(mach_const, h)
                vs = 0
                seg = "CR"
            elif h > h_const_mach:
                v = aero.mach2tas(mach_const, h)
                vs = vs_constmach
                seg = "MACH"
            elif h > h_const_cas:
                v = aero.cas2tas(vcas_const, h)
                vs = vs_constcas
                seg = "CAS"
            elif h > 1000 * aero.ft:
                v = v + a * dt
                if aero.tas2cas(v, h) < v_app:
                    v = aero.cas2tas(v_app, h)
                vs = vs_post_constcas
                seg = "POST-CAS"
            elif h > 0:
                v = v_app
                vs = vs_fa
                seg = "FA"
            else:
                h = 0
                vs = 0
                v = v + a_lnd * dt
                seg = "LD"

                if v <= 0:
                    break

        data = np.array(data)
        ndata = len(data)
        datadict = {
            "t": data[:, 0],
            "h": data[:, 1] + np.random.normal(0, self.sigma_h, ndata),
            "s": data[:, 2] + np.random.normal(0, self.sigma_s, ndata),
            "v": data[:, 3] + np.random.normal(0, self.sigma_v, ndata),
            "vs": data[:, 4] + np.random.normal(0, self.sigma_vs, ndata),
            "seg": data[:, 5],
            "cas_const_de": cas_const,
            "vcas_const_de": vcas_const,
            "mach_const_de": mach_const,
            "alt_cr": alt_cr,
        }

        return datadict