2024-09-28 07:39:44 +00:00
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package main
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2024-09-28 08:17:05 +00:00
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import (
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"math"
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"time"
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)
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2024-09-28 07:39:44 +00:00
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// momentaryOutput is an output that can be triggered for 500ms.
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type momentaryOutput struct {
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// output of the block.
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output bool
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// scheduledOff is when the block should be outputting false again.
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scheduledOff time.Time
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}
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func (m *momentaryOutput) process() {
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m.output = m.scheduledOff.After(time.Now())
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}
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func (m *momentaryOutput) trigger() {
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m.scheduledOff = time.Now().Add(time.Millisecond * 500)
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}
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// thresholdOutput outputs true if a given value is above a setpoint/threshold.
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// It contains debounce logic for processing noisy analog signals.
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type thresholdOutput struct {
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// output of the block.
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output bool
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// debounce is when the debouncer should be inactive again.
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debounce time.Time
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// threshold is the setpoint of the block.
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threshold float64
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}
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func (t *thresholdOutput) process(value float64) {
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if time.Now().Before(t.debounce) {
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return
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}
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new := value > t.threshold
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if new != t.output {
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t.output = new
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t.debounce = time.Now().Add(time.Second * 5)
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}
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}
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// ringbufferInput accumulates analog data up to limit samples, and calculates
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// an average.
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type ringbufferInput struct {
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data []float32
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limit uint
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// avg is the mean average of the samples in data, or 0.0 if no data is
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// present yet. This is the main output of the block.
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avg float32
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}
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func (r *ringbufferInput) process(input float32) {
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// TODO(q3k): use actual ringbuffer
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// TODO(q3k): optimize average calculation
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// TODO(q3k): precalculate value in mbar
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r.data = append(r.data, input)
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trim := len(r.data) - int(r.limit)
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if trim > 0 {
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r.data = r.data[trim:]
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}
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avg := float32(0.0)
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for _, v := range r.data {
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avg += v
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}
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if len(r.data) != 0 {
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avg /= float32(len(r.data))
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}
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r.avg = avg
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}
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// saturated returns true if the number of samples is at the configured limit.
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func (r *ringbufferInput) saturated() bool {
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return len(r.data) >= int(r.limit)
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}
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2024-09-28 08:17:05 +00:00
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type pfeifferVoltsToMbar struct {
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mbar float32
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}
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func (p *pfeifferVoltsToMbar) process(volts float32) {
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// Per Pirani probe docs.
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bar := math.Pow(10.0, float64(volts)-8.5)
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p.mbar = float32(bar * 1000.0)
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}
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