411 lines
11 KiB
Text
411 lines
11 KiB
Text
# Glider Instrumentation Toolkit
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#
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# Copyright (C) 2013-2014 Anton Gomez Alvedro
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#
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# This program is free software; you can redistribute it and/or
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# modify it under the terms of the GNU General Public License as
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# published by the Free Software Foundation; either version 2 of the
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# License, or (at your option) any later version.
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#
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# This program is distributed in the hope that it will be useful, but
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# WITHOUT ANY WARRANTY; without even the implied warranty of
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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# General Public License for more details.
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#
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# You should have received a copy of the GNU General Public License
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# along with this program; if not, write to the Free Software
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# Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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#
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# Features:
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# + Total energy compensated variometer
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# + Netto variometer
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# + Relative (Super Netto) variometer
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# + Configurable dampener for simulating needle response time
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# + Configurable averager
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# + Speed to fly computer
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#
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# TODO:
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# - add wind correction to speed-to-fly
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# - final glide computer
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io.include("updateloop.nas");
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var MPS2KPH = 3.6;
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var sqr = func(x) {x * x}
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var InstrumentComponent = {
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parents: [Updatable],
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output: 0,
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reset: func { me.output = 0 },
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};
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# This alias is for keeping backwards compatibility.
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# TODO: Refactor aircrafts that use it and remove this.
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var Instrument = UpdateLoop;
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##
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# Helper generator for updating a property on every element update
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#
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# Example:
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#
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# var needle = Dampener.new(
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# input: probe,
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# dampening: 2.8,
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# on_update: update_prop("/instrumentation/variometer/te-reading-mps"));
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#
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# See Aircraft/Instruments-3d/glider/vario/ilec-sc7.nas and
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# Aircraft/Generic/soaring-instrumentation-sdk.nas for usage examples.
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# You can also refer to the soaring sdk wiki page.
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var update_prop = func(property) {
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func(value) { setprop(property, value) }
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};
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# InputSwitcher
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# Selects output from one of multiple components given as inputs
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#
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# var lcd_controller = InputSwitcher.new(
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# inputs: Vector of objects connected to the input
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# active_input: (optional) Input number that is active at start
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# on_update: (optional) function to call whenever a new output is available
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var InputSwitcher = {
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parents: [InstrumentComponent],
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new: func(inputs, active_input = 0, on_update = nil) {
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return {
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parents: [me],
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inputs: inputs,
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active_input: active_input,
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on_update: on_update
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};
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},
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select_input: func(input_number) {
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me.active_input = input_number;
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me.update();
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},
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update: func {
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me.output = me.inputs[me.active_input].output;
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if (me.on_update != nil) me.on_update(me.output);
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}
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};
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# PropertyReader
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# Makes a property available at its output. Its purpose is to adapt properties
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# to the component model used by the library.
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#
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# var temperature = PropertyReader.new(
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# property: Property to read from
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# scale: Scale factor applied to the property value (output = scale * prop)
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var PropertyReader = {
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parents: [InstrumentComponent],
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new: func(property, scale = 1) {
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return {
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parents: [me],
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property: property,
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scale: scale
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};
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},
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update: func {
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me.output = me.scale * getprop(me.property);
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}
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};
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# YawString
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# The most important instrument in a glider. Simple, cheap and effective!
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#
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# var string = YawString.new(
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# on_update: update_prop("/instrumentation/yaw-string/deflection-deg");
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var YawString = {
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parents: [InstrumentComponent],
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new: func (on_update = nil) {
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return {
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parents: [me],
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on_update: on_update
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};
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},
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update: func {
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var airspeed = getprop("velocities/airspeed-kt");
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var noise = (airspeed < 54) ?
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math.sin(math.pi * airspeed / 54) * rand() : 0;
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me.output = noise + getprop("orientation/side-slip-deg");
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if (me.on_update != nil) me.on_update(me.output);
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}
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};
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# TotalEnergyProbe
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# Computes total energy variation by reading current airspeed and altitude
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#
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# var probe = TotalEnergyProbe.new(
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# on_update: (optional) function to call whenever a new output is available
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var TotalEnergyProbe = {
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parents: [InstrumentComponent],
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altitude: 0, # meters
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airspeed: 0, # m/s
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new: func(on_update = nil) {
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return {
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parents: [me],
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on_update: on_update
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};
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},
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reset: func {
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me.airspeed = getprop("/velocities/airspeed-kt") * KT2MPS;
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me.altitude = getprop("/position/altitude-ft") * FT2M;
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me.output = 0;
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},
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update: func(dt) {
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var altitude_now = getprop("/position/altitude-ft") * FT2M;
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var airspeed_now = getprop("/velocities/airspeed-kt") * KT2MPS;
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me.output = (altitude_now - me.altitude) / dt;
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me.output += (sqr(airspeed_now) - sqr(me.airspeed)) / (19.62 * dt);
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me.altitude = altitude_now;
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me.airspeed = airspeed_now;
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if (me.on_update != nil) me.on_update(me.output);
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}
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};
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# Dampener
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# Simple IIR exponential filter. Appropriate and efficient for simulating
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# mechanical needle dampening.
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#
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# var needle = Dampener.new(
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# input: Object connected to the dampeners input.
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# dampening: (optional) Time constant for the filter in seconds
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# scale: (optional) Scale factor applied to the input signal before filtering
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# on_update: (optional) function to call whenever a new output is available
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var Dampener = {
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parents: [InstrumentComponent],
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dampening: 0, # time constant of the exponential filter (sec)
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scale: 1,
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new: func(input, dampening = 3, scale = 1, on_update = nil) {
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return {
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parents: [me],
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input: input,
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dampening: dampening,
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scale: scale,
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on_update: on_update,
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};
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},
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update: func(dt) {
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var alfa = math.exp(-dt / me.dampening);
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me.output = me.output * alfa + me.input.output * me.scale * (1 - alfa);
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if (me.on_update != nil) me.on_update(me.output);
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}
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};
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# Averager
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# Provides a windowed moving average of its input signal. Window size is
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# set on construction, and is given in samples (i.e. not seconds).
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#
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# var averager = Averager.new(
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# input: Object connected to the averagers input.
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# size: (optional) window size in samples
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# on_update: (optional) function to call whenever a new output is available
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var Averager = {
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parents: [InstrumentComponent],
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new: func(input, buffer_size = 25, on_update = nil) {
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var m = { parents: [me] };
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m.input = input;
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m.on_update = on_update;
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m.size = buffer_size;
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m.sum = m.wp = 0;
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m.buffer = setsize([], buffer_size);
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m.reset();
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return m;
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},
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reset: func {
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me.sum = me.wp = me.output = 0;
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forindex (var i; me.buffer)
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me.buffer[i] = 0;
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},
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update: func {
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var new_value = me.input.output;
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me.sum = me.sum + new_value - me.buffer[me.wp];
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me.output = me.sum / me.size;
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me.buffer[me.wp] = new_value;
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if ((me.wp += 1) == me.size)
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me.wp = 0;
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if (me.on_update != nil) me.on_update(me.output);
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}
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};
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# PolarSolver
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# Helper object required for advanced soaring instrumentation.
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# Provides McCready speed-to-fly computations assuming a parabolic glider polar
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# (this approximation is frequently used in real instruments as well).
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#
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# Polar coeficients provided on construction correspond to the equation:
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# sink = coefs[0] * airspeed^2 + coefs[1] * airspeed + coefs[2]
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#
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# Note that sink is considered positive. Negative sink means.. lift!
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#
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# var solver = PolarSolver.new(
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# polar_coefs: [0.000364277, -0.0479199, 2.31644]
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# mass: Reference mass in Kg used while obtaining the polar above
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var PolarSolver = {
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min_sink: 0, # minimum sink m/s, according to glider polar
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new: func(polar_coefs, mass) {
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var m = { parents: [me] };
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m.reference_coefs = polar_coefs;
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m.coefs = polar_coefs;
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m.reference_mass = mass;
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m.total_mass = mass;
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m.min_sink = m.coefs[2] - (sqr(m.coefs[1]) / (4 * m.coefs[0]));
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return m;
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},
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set_total_mass: func(mass) {
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me.total_mass = mass;
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var load_factor = math.sqrt(mass / me.reference_mass);
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# Update active polar
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me.coefs[0] = me.reference_coefs[0] / load_factor;
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me.coefs[2] = me.reference_coefs[2] * load_factor;
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me.min_sink = me.coefs[2] - (sqr(me.coefs[1]) / (4 * me.coefs[0]));
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},
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speed_to_fly: func(mc, airmass_sink) {
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var speed = (mc + me.coefs[2] + airmass_sink) / me.coefs[0];
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return (speed > 0) ? math.sqrt(speed) : 0;
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},
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ld: func(airspeed) {
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return aispeed / me.sink(airspeed);
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},
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sink: func(airspeed) {
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return me.coefs[0] * sqr(airspeed)
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+ me.coefs[1] * airspeed + me.coefs[2];
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}
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};
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# NettoVario
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# The Netto variometer substract glider's sink rate for current airpseed from a
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# total energy reading. The resulting value is airmass' lift/sink in m/s.
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#
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# var netto = NettoVario.new(
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# te_probe: Object providing a total energy reading
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# polar_solver: Object providing a McCready implementation
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# on_update: (optional) function to call whenever a new output is available
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var NettoVario = {
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parents: [InstrumentComponent],
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new: func(te_probe, polar_solver, on_update=nil) {
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return {
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parents: [me],
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probe: te_probe,
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polar: polar_solver,
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on_update: on_update
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};
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},
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update: func {
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me.output = probe.output
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+ me.polar.sink(probe.airspeed);
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if (me.on_update != nil) me.on_update(me.output);
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}
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};
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# RelativeVario
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# The Relative (aka Super Netto) variometer tell you what climb rate would you
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# get if you slowed down to optimal thermaling speed.
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#
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# var snetto = RelativeVario.new(
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# te_probe: Object providing a total energy reading
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# polar_solver: Object providing a McCready implementation
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# on_update: (optional) function to call whenever a new output is available
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var RelativeVario = {
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new: func(te_probe, polar_solver, on_update=nil) {
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return {
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parents: [me, NettoVario.new(te_probe, polar_solver, on_update)]
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};
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},
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update: func {
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me.output = probe.output
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+ me.polar.sink(probe.airspeed)
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- me.polar.min_sink;
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if (me.on_update != nil) me.on_update(me.output);
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}
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};
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# SpeedCmdVario
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# The speed command variometer tells you how fast or slow your airspeed is with
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# respect to the optimal speed-to-fly (computed according to McCready theory).
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#
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# var speedcmd = SpeedCmdVario.new(
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# te_probe: Object providing a total energy reading
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# polar_solver: Object providing a McCready implementation
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# netto: (optional) Object providing a Netto reading
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# on_update: (optional) function to call whenever a new output is available
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var SpeedCmdVario = {
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parents: [InstrumentComponent],
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mc: 0, # mccready setting
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new: func(te_probe, polar_solver, netto = nil, on_update = nil) {
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return {
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parents: [me],
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polar: polar_solver,
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probe: te_probe,
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netto: netto or NettoVario.new(te_probe, polar_solver),
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update_netto: (netto == nil),
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on_update: on_update
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};
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},
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update: func {
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if (me.update_netto) me.netto.update();
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var target_speed = me.polar.speed_to_fly(me.mc, -me.netto.output);
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me.output = me.probe.airspeed * MPS2KPH - target_speed;
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if (me.on_update != nil) me.on_update(me.output);
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}
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};
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