Exemplo n.º 1
0
def Case3(cd0,
          k1,
          k2,
          V,
          Rc,
          h,
          alpha,
          beta,
          WS_range=np.arange(5, 300, 1),
          g0=9.81):
    '''
    calculates the wing loading for constant altitude/ speed turn
    designing for turn radius
    '''
    T_W = []
    W_S = []

    _, _, rho = isa(h)
    q = 0.5 * rho * V**2

    n = np.sqrt(1 + ((V**2) / (g0 * Rc))**2)

    for WS in WS_range:
        TW = beta / alpha * (k1 * n**2 * beta / q * WS + k2 * n + cd0 /
                             (beta / q * WS))
        T_W.append(1 / (V * TW))
        #        T_W.append(TW)
        W_S.append(WS)

    plt.plot(W_S, T_W, label='Case 3', linewidth=4)
Exemplo n.º 2
0
def Case00(cd0,
           k1,
           k2,
           dVdt,
           V,
           h,
           alpha,
           beta,
           WS_range=np.arange(5, 300, 1),
           g0=9.81):
    '''
    calculates the wing loading for accelerating climb
    designing for climb 
    '''
    T_W = []
    W_S = []

    _, _, rho = isa(h)
    q = 0.5 * rho * V**2

    n = 1 + dVdt / g0

    for WS in WS_range:
        TW = q / alpha * (cd0 / WS + k1 * (n * beta / q)**2 * WS + k2 * n *
                          beta / q) + beta / alpha * (1 + 1 / g0 * dVdt)
        T_W.append(1 / (V * TW))
        #        T_W.append(TW)
        W_S.append(WS)

    plt.plot(W_S, T_W, label='Case 00', linewidth=4)
Exemplo n.º 3
0
def Case8(cd0,
          k1,
          k2,
          V,
          dhdt,
          CL,
          h,
          alpha,
          beta,
          WS_range=np.arange(5, 300, 1)):
    '''
    calculates the wing loading for service ceiling
    designing for maximum altitude
    '''
    T_W = []
    W_S = []

    _, _, rho = isa(h)
    q = 0.5 * rho * V**2

    for WS in WS_range:
        TW = beta / alpha * (k1 * beta / q * WS + k2 + cd0 /
                             (beta / q * WS) + 1 / V * dhdt)
        T_W.append(1 / (V * TW))
        #        T_W.append(TW)
        W_S.append(WS)

    plt.plot(W_S, T_W, label='Case 8', linewidth=4)
Exemplo n.º 4
0
def Case4(cd0,
          k1,
          k2,
          dVdt,
          V,
          h,
          alpha,
          beta,
          WS_range=np.arange(5, 300, 1),
          g0=9.81):
    '''
    calculates the wing loading for horizontal acceleration
    designing for dVdt (acceleration)
    '''
    T_W = []
    W_S = []

    _, _, rho = isa(h)
    q = 0.5 * rho * V**2

    for WS in WS_range:
        TW = beta / alpha * (k1 * beta / q * WS + k2 + cd0 /
                             (beta / q * WS) + 1 / g0 * dVdt)
        T_W.append(1 / (V * TW))
        #        T_W.append(TW)
        W_S.append(WS)

    plt.plot(W_S, T_W, label='Case 4', linewidth=4)
Exemplo n.º 5
0
def noise_heat(xyzsource, d_inch, P_h, T, B, RPM, h):
    '''
    Calculates the SPL on a set of points.
    Also produces heat map of the surroundings
    '''
    R_ft = 0.0833333333 * d_inch / 2
    m = 1
    gamma, R, Temp = 1.4, 287, isa(h)[1]
    M_t = V_r(RPM, d_inch, 1) * 0.3048 / np.sqrt(gamma * R * Temp)
    V_07 = V_r(RPM, d_inch, 0.7)

    #Assumption blade area
    A_b = 2 / B * 1 / 12

    SPLlst = list()
    xrange = np.arange(-0.6, 1 + 0.01, 0.01)
    yrange = np.arange(-1.6, 1.6 + 0.01, 0.01)
    for x in xrange:
        for y in yrange:
            xyzobserver = [x, y, 0]
            S, theta = position(xyzsource, xyzobserver)

            p_rn = list()
            p_v = list()
            for S, theta in zip(S, theta):
                #ORDERED ROTATIONAL NOISE PRESSURE AT OBSERVER
                rotationp = p_m(m, S, R_ft, P_h, T, B, M_t, theta)
                p_rn.append(rotationp)
                #VORTEX NOISE AT OBSERVER
                vortexSPL = SPL_vortex(A_b, V_07)
                vortexSPL_obs = SPL_to_PWL_dist(vortexSPL, 300, S_obs=S)
                vortexp = SPL_to_p(vortexSPL_obs)
                p_v.append(vortexp)

            p_sum = sum(p_rn) + sum(p_v)
            SPL = p_to_SPL(p_sum)
            if SPL > 120:
                SPLlst.append(120)
            else:
                SPLlst.append(SPL)

    SPLlst = np.array(SPLlst).reshape(len(xrange), len(yrange))
    window = [yrange[0], yrange[-1], xrange[-1], xrange[0]]
    plt.imshow(SPLlst, cmap='Reds', extent=window)
    plt.colorbar()
    plt.plot(FW_skeleton[1], FW_skeleton[0], "black")
    return SPLlst
Exemplo n.º 6
0
def Case1(V, h, cd0, alpha, WS_range=np.arange(5, 300, 1)):
    '''
    calculates the wing loading for constant altitude and speed cruise
    designing for cruise speed
    '''
    T_W = []
    W_S = []

    _, _, rho = isa(h)
    q = 0.5 * rho * V**2

    for WS in WS_range:
        TW = (q * cd0) / (alpha * WS)
        T_W.append(1 / (V * TW))
        #        T_W.append(TW)
        W_S.append(WS)

    plt.plot(W_S, T_W, label='Case 1', linewidth=4)
Exemplo n.º 7
0
def Case2(cd0, k1, k2, V, h, alpha, beta, WS_range=np.arange(5, 300, 1)):
    '''
    calculates the wing loading for constant speed climb
    designing for climb 
    '''
    T_W = []
    W_S = []

    _, _, rho = isa(h)
    q = 0.5 * rho * V**2

    for WS in WS_range:
        TW = beta / alpha * (k1 * beta / q * WS + k2 + cd0 /
                             (beta / q * WS) + 1)
        T_W.append(1 / (V * TW))
        #        T_W.append(TW)
        W_S.append(WS)

    plt.plot(W_S, T_W, label='Case 2', linewidth=4)
Exemplo n.º 8
0
def req_noise(xyzsource, d_inch, P_h, T, B, RPM, h, r, CG, PWL_req):

    SPL_req = PWL_to_SPL(PWL_req, r)
    print(SPL_req)
    SPLlst = list()

    R_ft = 0.0833333333 * d_inch / 2
    m = 1
    gamma, R, Temp = 1.4, 287, isa(h)[1]
    M_t = V_r(RPM, d_inch, 1) * 0.3048 / np.sqrt(gamma * R * Temp)
    V_07 = V_r(RPM, d_inch, 0.7)

    #Assumption blade area
    A_b = 2 / B * 1 / 12
    thetalst = list()

    for theta in np.arange(0, 360 + 1, 1):

        x = r * np.sin(theta)
        y = r * np.cos(theta)
        thetalst.append(theta)

        xyzobserver = [x, y, 0]
        S, theta = position(xyzsource, xyzobserver)

        p_rn = list()
        p_v = list()

        for S, theta in zip(S, theta):
            #ORDERED ROTATIONAL NOISE PRESSURE AT OBSERVER
            rotationp = p_m(m, S, R_ft, P_h, T, B, M_t, theta)
            p_rn.append(rotationp)
            #VORTEX NOISE AT OBSERVER
            vortexSPL = SPL_vortex(A_b, V_07)
            vortexSPL_obs = SPL_to_PWL_dist(vortexSPL, 300, S_obs=S)
            vortexp = SPL_to_p(vortexSPL_obs)
            p_v.append(vortexp)

        p_sum = sum(p_rn + p_v)

        SPL = p_to_SPL(p_sum)
        SPLlst.append(SPL)

    return max(SPLlst), thetalst, SPLlst


#BUTTERFLY PLOT
#plst=list()
#thetalst=list()
#for theta in np.arange(0,2*np.pi*1.026,0.05):
#    p=p_m(1,3,0.645833333075,1.36,12.521858094085683,3, 0.75, theta)
#    if p>0:
#        thetalst.append(theta)
#        plst.append(p)
#    else:
#        thetalst.append(theta)
#        plst.append(-p)
#
#plt.plot(thetalst,plst)
#plt.polar(thetalst,plst)
#plt.show()
#plt.ylabel('p')
#plt.xlabel('theta')