def _alt2ROC(prop, alt): """ calculate ROC for an altitude """ temp = SA.isa2temp(isa_dev, alt) calc_pwr = alt2pwr(alt, rpm = rpm, MP_max = MP_max, temp = temp) * pwr_factor cas = alt2roc_speed(alt, climb_speed = climb_speed) eas = A.cas2eas(cas, alt) ROC = roc(prop, alt, eas, weight, calc_pwr, rpm, rv = rv, \ wing_area = wing_area) return ROC
def _alt2ROC(prop, alt): """ calculate ROC for an altitude """ temp = SA.isa2temp(isa_dev, alt) calc_pwr = alt2pwr(alt, rpm=rpm, MP_max=MP_max, temp=temp) * pwr_factor cas = alt2roc_speed(alt, climb_speed=climb_speed) eas = A.cas2eas(cas, alt) ROC = roc(prop, alt, eas, weight, calc_pwr, rpm, rv = rv, \ wing_area = wing_area) return ROC
def cas2cl( cas, altitude, weight, wing_area, load_factor=1, speed_units=default_speed_units, alt_units=default_alt_units, weight_units=default_weight_units, area_units=default_area_units, ): """ Returns the coefficient of lift, given calibrated airspeed, altitude, weight, and wing area. Load factor is an optional input. The load factor, if not provided, defaults to 1. Example: if the wing area is 15 square meters, and the weight is 1500 kg, and the cas is 200 km/h, at 3,000 meter altitude in a stabilized 45 degree bank turn (so the load factor = 2**0.5), >>> S = 15 >>> W = 1500 >>> CAS = 200 >>> Alt = 3000 >>> cas2cl(CAS, Alt, W, S, load_factor = 2**0.5, speed_units='km/h',\ alt_units='m', weight_units='kg', area_units='m**2') 0.7357813111713088 """ eas = A.cas2eas(cas, altitude, speed_units, alt_units) Cl = eas2cl( eas, weight, wing_area, load_factor, speed_units, weight_units, area_units, ) return Cl
def cas2cl( cas, altitude, weight, wing_area, load_factor=1, speed_units=default_speed_units, alt_units=default_alt_units, weight_units=default_weight_units, area_units=default_area_units, ): """ Returns the coefficient of lift, given calibrated airspeed, altitude, weight, and wing area. Load factor is an optional input. The load factor, if not provided, defaults to 1. Example: if the wing area is 15 square meters, and the weight is 1500 kg, and the cas is 200 km/h, at 3,000 meter altitude in a stabilized 45 degree bank turn (so the load factor = 2**0.5), >>> S = 15 >>> W = 1500 >>> CAS = 200 >>> Alt = 3000 >>> cas2cl(CAS, Alt, W, S, load_factor = 2**0.5, speed_units='km/h',\ alt_units='m', weight_units='kg', area_units='m**2') 0.73578131117130885 """ eas = A.cas2eas(cas, altitude, speed_units, alt_units) Cl = eas2cl( eas, weight, wing_area, load_factor, speed_units, weight_units, area_units, ) return Cl
def roc_vs_temp(prop, alt_max = 20000, alt_interval=2000, weight=1800, temps=[-20,0,20,40], pwr='max', \ pwr_factor=1.0, climb_speed='max', output='raw'): """ Returns the rates of climb at various temperatures """ if pwr == 'max': rpm = 2650 MP_max = 30 elif pwr == 'cc': rpm = 2500 MP_max = 25 elif pwr == 2500: rpm = 2500 MP_max = 30 else: raise ValueError, "pwr must be on of 'max', 'cc', or 2500" alt = 0 while alt<alt_max: press = SA.alt2press(alt) MP = press - (29.9213 - 28.6) cas = alt2roc_speed(alt, climb_speed = climb_speed) eas = A.cas2eas(cas, alt) # for temp in temps: # print temp, '\t\t\t', # print '\n', print '%.0f\t%.0f\t%.0f\t' % (weight, alt, cas), for temp in temps: # power = IO.pwr(rpm, MP, alt, temp) * pwr_factor power = alt2pwr(alt, rpm = rpm, MP_max = MP_max, temp = temp) ROC = roc(prop, alt, eas, weight, power, rpm, temp) /10 ROC = int('%.0f' % (ROC)) * 10 print '%.0f\t' % (ROC), print '\n' alt += alt_interval
def roc_vs_temp(prop, alt_max = 20000, alt_interval=2000, weight=1800, temps=[-20,0,20,40], pwr='max', \ pwr_factor=1.0, climb_speed='max', output='raw'): """ Returns the rates of climb at various temperatures """ if pwr == 'max': rpm = 2650 MP_max = 30 elif pwr == 'cc': rpm = 2500 MP_max = 25 elif pwr == 2500: rpm = 2500 MP_max = 30 else: raise ValueError("pwr must be on of 'max', 'cc', or 2500") alt = 0 while alt < alt_max: press = SA.alt2press(alt) MP = press - (29.9213 - 28.6) cas = alt2roc_speed(alt, climb_speed=climb_speed) eas = A.cas2eas(cas, alt) # for temp in temps: # print temp, '\t\t\t', # print '\n', print('%.0f\t%.0f\t%.0f\t' % (weight, alt, cas), end=' ') for temp in temps: # power = IO.pwr(rpm, MP, alt, temp) * pwr_factor power = alt2pwr(alt, rpm=rpm, MP_max=MP_max, temp=temp) ROC = roc(prop, alt, eas, weight, power, rpm, temp) / 10 ROC = int('%.0f' % (ROC)) * 10 print('%.0f\t' % (ROC), end=' ') print('\n') alt += alt_interval
#!/sw/bin/python import airspeed as A alts = range(39000, -1, -1000) Ms = range(30, 79, 2) + [79] + [80, 82, 84, 85] print " EAS | Mach |" print " hp |", for M in Ms: print "%0.2f|" % (M / 100.), print "\n", for alt in alts: print "%5i|" % (alt), for M in Ms: CAS = A.mach_alt2cas(M / 100., alt) print "%4.0f|" % (A.cas2eas(CAS, alt)), print "\n",
#! /sw/bin/python2.7 """Return EAS given CAS and Pressure Altitude""" import airspeed import argparse parser = argparse.ArgumentParser( description='Return EAS for a given CAS and pressure altitude') parser.add_argument('CAS', type=float, help='Calibrated Airspeed') parser.add_argument('HP', type=float, help='Pressure Altitude') parser.add_argument( '--speed_units', required=False, default='kt', help= 'airspeed units - one of "kt", "mph", "km/h", "ft/s" or "m/s". Defaults to "kt".' ) parser.add_argument( '--alt_units', required=False, default='ft', help= 'altitude units - one of feet ("ft"), metres ("m"), kilometres ("km"), statute miles, ("sm") or nautical miles ("nm"). Defaults to "ft".' ) args = parser.parse_args() print( airspeed.cas2eas(args.CAS, args.HP, speed_units=args.speed_units, alt_units=args.alt_units))
#!/sw/bin/python import airspeed as A alts=range(39000,-1,-1000) Ms=range(30, 79, 2) + [79] + [80, 82, 84, 85] print "Mach | EAS" print " hp |", for M in Ms: print "%0.2f|" % (M / 100.), print "\n", for alt in alts: print "%5i|" % (alt), for M in Ms: CAS = A.mach_alt2cas(M/100., alt) print "%4.0f|" % (A.cas2eas(CAS, alt)), print "\n",
def climb_data(prop, weight = 1800., alt_max = 20000., TO_fuel = 0, TO_dist = 0, \ fuel_units = 'USG', alt_interval = 500., isa_dev = 0, temp_units = 'C', \ rv = '8', wing_area = 110., pwr = 'max', pwr_factor=1.0, \ climb_speed = 'max', output = 'raw'): """ Returns a table of climb performance vs altitude. The items in each row of the table are altitude, time, fuel burned and distance. Time is in units of minutes, rounded to the nearest half minute. Fuel units are selectable, with a default of USG. Distances are in nm. The output may be specified as raw, latex (a LaTeX table for the POH), or array. pwr may be 'max', 'cc' (cruise climb = 2500 rpm and 25") or 2500 (2500 rpm and full throttle) climb_speed may be 'max' (Vy), 'cc' (120 kt to 10,000 ft, then reducing by 4 kt/1000 ft) or 'norm' (100 kt to 10,000 ft, then reducing by 2 kt/1000 ft) Note: compared cruise range for all climb speed and power. The predicted results are all within 1.5 nm of range. Thus there is no advantage to using anything but Vy and max power. """ def _alt2ROC(prop, alt): """ calculate ROC for an altitude """ temp = SA.isa2temp(isa_dev, alt) calc_pwr = alt2pwr(alt, rpm = rpm, MP_max = MP_max, temp = temp) * pwr_factor cas = alt2roc_speed(alt, climb_speed = climb_speed) eas = A.cas2eas(cas, alt) ROC = roc(prop, alt, eas, weight, calc_pwr, rpm, rv = rv, \ wing_area = wing_area) return ROC alt = 0 time = 0 fuel_used = U.avgas_conv(TO_fuel, from_units = fuel_units, to_units = 'lb') weight = weight - fuel_used dist = TO_dist if pwr == 'max': # rpm = 2700 rpm = 2650 MP_max = 30 elif pwr == 'cc': rpm = 2500 MP_max = 25 elif pwr == 2500: rpm = 2500 MP_max = 30 else: raise ValueError, "pwr must be one of 'max', 'cc', or 2500" if output == 'raw': print S.center('Altitude', 10), print S.center('ROC', 10), print S.center('Time', 10), print S.center('Fuel Used', 10), print S.center('Dist', 10), print S.center('Speed', 10) print S.center('(ft)', 10), print S.center('(ft/mn)', 10), print S.center('(mn)', 10), f_units = '(' + fuel_units + ')' print S.center(f_units, 10), print S.center('(nm)', 10), print S.center('(KCAS)', 10) # data for MSL print S.rjust(locale.format('%.0f', 0, True), 7), # calculate ROC at MSL print S.rjust(locale.format('%.0f', round(_alt2ROC(prop, 0) / 10.) * 10, \ True), 10), print S.rjust('%.1f' % (0), 10), print S.rjust('%.1f' % (TO_fuel), 10), print S.rjust('%.1f' % (TO_dist), 10), print S.rjust('%3d' % (alt2roc_speed(0, climb_speed = climb_speed)), 10) elif output == 'latex': temp = 15 + isa_dev MSL_line = [] MSL_line.append(str(locale.format('%.0f', weight, True))) MSL_line.append('0') MSL_line.append(str(locale.format('%.0f', temp))) MSL_line.append(str(locale.format('%.0f', alt2roc_speed(0, \ climb_speed = climb_speed)))) MSL_line.append(str(locale.format('%.0f', round(_alt2ROC(prop, 0) / 10.)\ * 10, True))) MSL_line.append('0') MSL_line.append(str(TO_fuel)) MSL_line.append(str(TO_dist)) print '&'.join(MSL_line) + '\\\\' print '\\hline' elif output == 'array': # no header rows, but make blank array array = [[0,0,TO_fuel,0]] calc_alt = alt_interval / 2. while calc_alt < alt_max: temp = SA.isa2temp(isa_dev, calc_alt) pwr = alt2pwr(calc_alt, rpm = rpm, MP_max = MP_max, temp = temp) calc_pwr = pwr * pwr_factor cas = alt2roc_speed(calc_alt, climb_speed = climb_speed) eas = A.cas2eas(cas, calc_alt) tas = A.cas2tas(cas, calc_alt, temp = temp, temp_units = temp_units) tas_fts = U.speed_conv(tas, from_units = 'kt', to_units = 'ft/s') ROC = roc(prop, calc_alt, eas, weight, calc_pwr, rpm, rv = rv, \ wing_area = wing_area) roc_fts = ROC / 60 fuel_flow = IO.pwr2ff(pwr, rpm, ff_units = 'lb/hr') slice_time = alt_interval / roc_fts slice_dist = tas_fts * slice_time slice_fuel = fuel_flow * slice_time / 3600 fuel_used += slice_fuel fuel_out = (U.avgas_conv(fuel_used, from_units = 'lb', \ to_units = fuel_units)) weight -= slice_fuel alt += alt_interval cas_out = alt2roc_speed(alt, climb_speed = climb_speed) temp_out = SA.isa2temp(isa_dev, alt) ROC = _alt2ROC(prop, alt) time += slice_time / 60 dist += slice_dist / 6076.115 if output == 'raw': print S.rjust(locale.format('%.0f', alt, True), 7), # calculate ROC at the displayed altitude print S.rjust(locale.format('%.0f', ROC, True), 10), print S.rjust('%.1f' % (time), 10), print S.rjust('%.1f' % (fuel_out), 10), print S.rjust('%.1f' % (dist), 10), print S.rjust('%3d' % (int(cas_out)), 10) elif output == 'latex': line = [] line.append(str(locale.format('%.0f', alt, True))) line.append(str(locale.format('%.0f', round(temp_out)))) line.append(str(locale.format('%.0f', cas_out))) line.append(str(locale.format('%.0f', round(ROC / 10.) * 10, True))) line.append(str(locale.format('%.0f', time))) line.append(str(locale.format('%.1f', fuel_out))) line.append(str(locale.format('%.0f', dist))) print '&' + '&'.join(line) + '\\\\' print '\\hline' elif output == 'array': array.append([alt, time, fuel_out, dist]) calc_alt += alt_interval if output == 'array': return array
#! /sw/bin/python2.7 """Return EAS given CAS and Pressure Altitude""" import airspeed import argparse parser = argparse.ArgumentParser(description='Return EAS for a given CAS and pressure altitude') parser.add_argument('CAS', type=float, help='Calibrated Airspeed') parser.add_argument('HP', type=float, help='Pressure Altitude') parser.add_argument('--speed_units', required=False, default='kt', help='airspeed units - one of "kt", "mph", "km/h", "ft/s" or "m/s". Defaults to "kt".') parser.add_argument('--alt_units', required=False, default='ft', help='altitude units - one of feet ("ft"), metres ("m"), kilometres ("km"), statute miles, ("sm") or nautical miles ("nm"). Defaults to "ft".') args = parser.parse_args() print(airspeed.cas2eas(args.CAS, args.HP, speed_units=args.speed_units, alt_units=args.alt_units))
def climb_data(prop, weight = 1800., alt_max = 20000., TO_fuel = 0, TO_dist = 0, \ fuel_units = 'USG', alt_interval = 500., isa_dev = 0, temp_units = 'C', \ rv = '8', wing_area = 110., pwr = 'max', pwr_factor=1.0, \ climb_speed = 'max', output = 'raw'): """ Returns a table of climb performance vs altitude. The items in each row of the table are altitude, time, fuel burned and distance. Time is in units of minutes, rounded to the nearest half minute. Fuel units are selectable, with a default of USG. Distances are in nm. The output may be specified as raw, latex (a LaTeX table for the POH), or array. pwr may be 'max', 'cc' (cruise climb = 2500 rpm and 25") or 2500 (2500 rpm and full throttle) climb_speed may be 'max' (Vy), 'cc' (120 kt to 10,000 ft, then reducing by 4 kt/1000 ft) or 'norm' (100 kt to 10,000 ft, then reducing by 2 kt/1000 ft) Note: compared cruise range for all climb speed and power. The predicted results are all within 1.5 nm of range. Thus there is no advantage to using anything but Vy and max power. """ def _alt2ROC(prop, alt): """ calculate ROC for an altitude """ temp = SA.isa2temp(isa_dev, alt) calc_pwr = alt2pwr(alt, rpm=rpm, MP_max=MP_max, temp=temp) * pwr_factor cas = alt2roc_speed(alt, climb_speed=climb_speed) eas = A.cas2eas(cas, alt) ROC = roc(prop, alt, eas, weight, calc_pwr, rpm, rv = rv, \ wing_area = wing_area) return ROC alt = 0 time = 0 fuel_used = U.avgas_conv(TO_fuel, from_units=fuel_units, to_units='lb') weight = weight - fuel_used dist = TO_dist if pwr == 'max': # rpm = 2700 rpm = 2650 MP_max = 30 elif pwr == 'cc': rpm = 2500 MP_max = 25 elif pwr == 2500: rpm = 2500 MP_max = 30 else: raise ValueError("pwr must be one of 'max', 'cc', or 2500") if output == 'raw': print(S.center('Altitude', 10), end=' ') print(S.center('ROC', 10), end=' ') print(S.center('Time', 10), end=' ') print(S.center('Fuel Used', 10), end=' ') print(S.center('Dist', 10), end=' ') print(S.center('Speed', 10)) print(S.center('(ft)', 10), end=' ') print(S.center('(ft/mn)', 10), end=' ') print(S.center('(mn)', 10), end=' ') f_units = '(' + fuel_units + ')' print(S.center(f_units, 10), end=' ') print(S.center('(nm)', 10), end=' ') print(S.center('(KCAS)', 10)) # data for MSL print(S.rjust(locale.format('%.0f', 0, True), 7), end=' ') # calculate ROC at MSL print(S.rjust(locale.format('%.0f', round(_alt2ROC(prop, 0) / 10.) * 10, \ True), 10), end=' ') print(S.rjust('%.1f' % (0), 10), end=' ') print(S.rjust('%.1f' % (TO_fuel), 10), end=' ') print(S.rjust('%.1f' % (TO_dist), 10), end=' ') print(S.rjust('%3d' % (alt2roc_speed(0, climb_speed=climb_speed)), 10)) elif output == 'latex': temp = 15 + isa_dev MSL_line = [] MSL_line.append(str(locale.format('%.0f', weight, True))) MSL_line.append('0') MSL_line.append(str(locale.format('%.0f', temp))) MSL_line.append(str(locale.format('%.0f', alt2roc_speed(0, \ climb_speed = climb_speed)))) MSL_line.append(str(locale.format('%.0f', round(_alt2ROC(prop, 0) / 10.)\ * 10, True))) MSL_line.append('0') MSL_line.append(str(TO_fuel)) MSL_line.append(str(TO_dist)) print('&'.join(MSL_line) + '\\\\') print('\\hline') elif output == 'array': # no header rows, but make blank array array = [[0, 0, TO_fuel, 0]] calc_alt = alt_interval / 2. while calc_alt < alt_max: temp = SA.isa2temp(isa_dev, calc_alt) pwr = alt2pwr(calc_alt, rpm=rpm, MP_max=MP_max, temp=temp) calc_pwr = pwr * pwr_factor cas = alt2roc_speed(calc_alt, climb_speed=climb_speed) eas = A.cas2eas(cas, calc_alt) tas = A.cas2tas(cas, calc_alt, temp=temp, temp_units=temp_units) tas_fts = U.speed_conv(tas, from_units='kt', to_units='ft/s') ROC = roc(prop, calc_alt, eas, weight, calc_pwr, rpm, rv = rv, \ wing_area = wing_area) roc_fts = ROC / 60 fuel_flow = IO.pwr2ff(pwr, rpm, ff_units='lb/hr') slice_time = alt_interval / roc_fts slice_dist = tas_fts * slice_time slice_fuel = fuel_flow * slice_time / 3600 fuel_used += slice_fuel fuel_out = (U.avgas_conv(fuel_used, from_units = 'lb', \ to_units = fuel_units)) weight -= slice_fuel alt += alt_interval cas_out = alt2roc_speed(alt, climb_speed=climb_speed) temp_out = SA.isa2temp(isa_dev, alt) ROC = _alt2ROC(prop, alt) time += slice_time / 60 dist += slice_dist / 6076.115 if output == 'raw': print(S.rjust(locale.format('%.0f', alt, True), 7), end=' ') # calculate ROC at the displayed altitude print(S.rjust(locale.format('%.0f', ROC, True), 10), end=' ') print(S.rjust('%.1f' % (time), 10), end=' ') print(S.rjust('%.1f' % (fuel_out), 10), end=' ') print(S.rjust('%.1f' % (dist), 10), end=' ') print(S.rjust('%3d' % (int(cas_out)), 10)) elif output == 'latex': line = [] line.append(str(locale.format('%.0f', alt, True))) line.append(str(locale.format('%.0f', round(temp_out)))) line.append(str(locale.format('%.0f', cas_out))) line.append(str(locale.format('%.0f', round(ROC / 10.) * 10, True))) line.append(str(locale.format('%.0f', time))) line.append(str(locale.format('%.1f', fuel_out))) line.append(str(locale.format('%.0f', dist))) print('&' + '&'.join(line) + '\\\\') print('\\hline') elif output == 'array': array.append([alt, time, fuel_out, dist]) calc_alt += alt_interval if output == 'array': return array