mirror
/
vk3cpu
kopia lustrzana https://github.com/miguelvaca/vk3cpu
1
0
Forkuj 0
Kod Zgłoszenia Packages Projekty Wydania Wiki Aktywność

Added capacitor voltage

pull/2/head
miguel 2020-10-19 00:15:40 +11:00
rodzic 61ce4dc6cb
commit 72de66f5f4
1 zmienionych plików z 68 dodań i 28 usunięć
Pokaż statystyki Ściągnij plik aktualizacji Ściągnij plik porównania Expand all files Collapse all files

96
magloop.html
Wyświetl plik

@ -260,57 +260,77 @@
return retval;
}
function capacitorVoltage(frequency) {
const Vcap = Math.sqrt(transmit_power_slider.value * inductiveReactance(frequency) * qualityFactor(frequency));
return Vcap;
}
function calculateCapacitorVoltage() {
var retval = [];
frequencies.forEach(freq => {
const Vcap = capacitorVoltage(freq);
retval.push({x:freq, y:Vcap});
});
return retval;
}
loop_diameter_slider.oninput = function() {
loop_diameter_value.innerHTML = this.value;
updateFrequencies();
myChart.data.datasets[0].data = calculateRadiationResistance();
myChart.data.datasets[1].data = calculateInductiveReactance();
myChart.data.datasets[2].data = calculateTuningCapacitor();
myChart.data.datasets[3].data = calculateLossResistance();
myChart.data.datasets[4].data = calculateEfficiencyFactor();
myChart.data.datasets[5].data = calculateQualityFactor();
myChart.data.datasets[6].data = calculateBandwidth();
myChart.data.datasets[0].data = calculateTuningCapacitor();
myChart.data.datasets[1].data = calculateBandwidth();
myChart.data.datasets[2].data = calculateEfficiencyFactor();
myChart.data.datasets[3].data = calculateRadiationResistance();
myChart.data.datasets[4].data = calculateInductiveReactance();
myChart.data.datasets[5].data = calculateLossResistance();
myChart.data.datasets[6].data = calculateQualityFactor();
myChart.data.datasets[7].data = calculateCapacitorVoltage();
myChart.update();
}
conductor_diameter_slider.oninput = function() {
conductor_diameter_value.innerHTML = this.value;
myChart.data.datasets[0].data = calculateRadiationResistance();
myChart.data.datasets[1].data = calculateInductiveReactance();
// myChart.data.datasets[2].data = calculateTuningCapacitor();
myChart.data.datasets[3].data = calculateLossResistance();
myChart.data.datasets[4].data = calculateEfficiencyFactor();
myChart.data.datasets[5].data = calculateQualityFactor();
myChart.data.datasets[6].data = calculateBandwidth();
myChart.data.datasets[0].data = calculateTuningCapacitor();
myChart.data.datasets[1].data = calculateBandwidth();
myChart.data.datasets[2].data = calculateEfficiencyFactor();
myChart.data.datasets[3].data = calculateRadiationResistance();
myChart.data.datasets[4].data = calculateInductiveReactance();
myChart.data.datasets[5].data = calculateLossResistance();
myChart.data.datasets[6].data = calculateQualityFactor();
myChart.data.datasets[7].data = calculateCapacitorVoltage();
myChart.update();
}
loop_turns_slider.oninput = function() {
loop_turns_value.innerHTML = this.value;
myChart.data.datasets[0].data = calculateRadiationResistance();
myChart.data.datasets[1].data = calculateInductiveReactance();
myChart.data.datasets[2].data = calculateTuningCapacitor();
myChart.data.datasets[3].data = calculateLossResistance();
myChart.data.datasets[4].data = calculateEfficiencyFactor();
myChart.data.datasets[5].data = calculateQualityFactor();
myChart.data.datasets[6].data = calculateBandwidth();
myChart.data.datasets[0].data = calculateTuningCapacitor();
myChart.data.datasets[1].data = calculateBandwidth();
myChart.data.datasets[2].data = calculateEfficiencyFactor();
myChart.data.datasets[3].data = calculateRadiationResistance();
myChart.data.datasets[4].data = calculateInductiveReactance();
myChart.data.datasets[5].data = calculateLossResistance();
myChart.data.datasets[6].data = calculateQualityFactor();
myChart.data.datasets[7].data = calculateCapacitorVoltage();
myChart.update();
}
loop_spacing_slider.oninput = function() {
loop_spacing_value.innerHTML = loop_spacing_slider.value;
myChart.data.datasets[0].data = calculateRadiationResistance();
myChart.data.datasets[1].data = calculateInductiveReactance();
myChart.data.datasets[2].data = calculateTuningCapacitor();
myChart.data.datasets[3].data = calculateLossResistance();
myChart.data.datasets[4].data = calculateEfficiencyFactor();
myChart.data.datasets[5].data = calculateQualityFactor();
myChart.data.datasets[6].data = calculateBandwidth();
myChart.data.datasets[0].data = calculateTuningCapacitor();
myChart.data.datasets[1].data = calculateBandwidth();
myChart.data.datasets[2].data = calculateEfficiencyFactor();
myChart.data.datasets[3].data = calculateRadiationResistance();
myChart.data.datasets[4].data = calculateInductiveReactance();
myChart.data.datasets[5].data = calculateLossResistance();
myChart.data.datasets[6].data = calculateQualityFactor();
myChart.data.datasets[7].data = calculateCapacitorVoltage();
myChart.update();
}
transmit_power_slider.oninput = function() {
transmit_power_value.innerHTML = this.value;
myChart.data.datasets[7].data = calculateCapacitorVoltage();
myChart.update();
}
heightAboveGround_slider.oninput = function() {
@ -386,6 +406,15 @@
data: calculateQualityFactor(),
borderWidth: 1,
yAxisID: 'qID'
},
{
label: 'V cap',
fill: false,
borderColor: 'rgb(150, 150, 0)',
backgroundColor: 'rgb(150, 150, 0)',
data: calculateCapacitorVoltage(),
borderWidth: 1,
yAxisID: 'vID'
}]
},
options: {
@ -465,6 +494,17 @@
},
position: 'right',
id: 'qID'
},{
type: 'linear',
display: true,
scaleLabel: {
display: true,
labelString: 'Volts',
fontColor: 'rgb(150, 150, 0)',
fontStyle: 'bold'
},
position: 'right',
id: 'vID'
}]
},
showLines: true