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Rate of Temperature Change calculation. Fixes #78

Neal Wilson 11 yıl önce
ebeveyn
işleme
1fa4bb5b35
2 değiştirilmiş dosya ile 159 ekleme ve 2 silme
  1. 154
    0
      src/rate.w
  2. 5
    2
      src/typica.w

+ 154
- 0
src/rate.w Dosyayı Görüntüle

@@ -0,0 +1,154 @@
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+@** A Rate of Change Indicator.
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+
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+\noindent A common metric used for understanding roast profiles is the rate of
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+temperature change over a given amount of time. When roasters discuss roast
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+profiles it is not uncommon to hear references to the change in temperature per
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+30 seconds or per minute, often with the sloppy shorthand $\Delta$ or with the
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+term Rate of Rise (RoR). This is most commonly calculated from the secant line
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+defined by two measurement points at the desired separation, however this may
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+not be the most useful way to calculate this value.
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+
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+The rate of change can be considered as its own data series which happens to be
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+derived from a primary measurement series. The interface for producing this
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+series can sensibly match other classes which store, forward, or manipulate
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+measurement data.
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+
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+@<Class declarations@>=
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+class RateOfChange : public QObject
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+{
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+	Q_OBJECT
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+	public:
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+		RateOfChange(int cachetime = 1, int scaletime = 1);
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+	public slots:
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+		void newMeasurement(Measurement measure);
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+		void setCacheTime(int seconds);
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+		void setScaleTime(int seconds);
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+	signals:
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+		void measurement(Measurement measure);
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+	private:
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+		int ct;
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+		int st;
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+		QList<Measurement> cache;
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+};
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+
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+@ The interesting part of this class is in the |newMeasurement()| method. This
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+is a slot method that will be called for every new measurement in the primary
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+series. We require at least two measurements before calculating a rate of
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+temperature change.
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+
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+@<RateOfChange implementation@>=
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+void RateOfChange::newMeasurement(Measurement measure)
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+{
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+	cache.append(measure);
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+	@<Remove stale measurements from rate cache@>@;
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+	if(cache.size() >= 2)
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+	{
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+		@<Calculate rate of change@>@;
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+	}
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+}
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+
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+@ To calculate the rate of temperature change we require at least two cached
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+measurements. Using only the most recent two measurements will result in a
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+highly volatile rate of change while using two data points that are more
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+separated will smooth out random fluctuations but provide a less immediate
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+response to a change in the rate of change. For this reason we provide two
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+parameters that can be adjusted independently: the amount of time we allow a
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+measurement to stay in the cache determines how far apart the measurements
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+used to calculate the rate of change are while a separate scale time is used
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+to determine how the calculated value is presented. We never allow fewer than
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+two cached values, but we can force the most volatile calculation by setting
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+the cache time to 0 seconds.
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+
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+@<Remove stale measurements from rate cache@>=
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+if(cache.size() > 2)
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+{
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+	bool done = false;
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+	while(!done)
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+	{
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+		if(cache.front().time().secsTo(cache.back().time()) > ct)
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+		{
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+			cache.removeFirst();
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+		}
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+		else
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+		{
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+			done = true;
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+		}
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+		if(cache.size() < 3)
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+		{
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+			done = true;
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+		}
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+	}
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+}
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+
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+@ To calculate the rate of change, we compare both the time and the
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+temperature of the first and last measurements in the cache and reduce this to
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+a change per second value. This is then multiplied by the scale time and sent
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+to whatever objects require the derived series data. Note that |tdiff| will
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+generally be very close to the cache time except where this is set to zero, but
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+it will almost never be exact. Basing the calculation on the data we have
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+instead of on the data we wish we had should result in better stability in the
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+derived series.
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+
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+@<Calculate rate of change@>=
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+double mdiff = cache.back().temperature() - cache.front().temperature();
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+double tdiff = cache.front().time().msecsTo(cache.back().time()) / 1000.0;
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+double dps = mdiff / tdiff;
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+double scale = dps * st;
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+emit measurement(Measurement(scale, cache.back().time(), cache.back().scale()));
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+
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+@ The rest of the class implementation is trivial.
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+
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+@<RateOfChange implementation@>=
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+RateOfChange::RateOfChange(int cachetime, int scaletime) : ct(cachetime), st(1)
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+{
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+	setScaleTime(scaletime);
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+}
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+
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+void RateOfChange::setCacheTime(int seconds)
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+{
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+	ct = seconds;
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+}
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+
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+void RateOfChange::setScaleTime(int seconds)
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+{
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+	st = (seconds > 0 ? seconds : 1);
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+}
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+
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+@ This is exposed to the host environment in the usual way.
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+
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+@<Function prototypes for scripting@>=
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+QScriptValue constructRateOfChange(QScriptContext *context, QScriptEngine *engine);
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+void setRateOfChangeProperties(QScriptValue value, QScriptEngine *engine);
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+
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+@ The constructor is registered with the scripting engine.
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+
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+@<Set up the scripting engine@>=
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+constructor = engine->newFunction(constructRateOfChange);
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+value = engine->newQMetaObject(&RateOfChange::staticMetaObject, constructor);
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+engine->globalObject().setProperty("RateOfChange", value);
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+
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+@ The constructor takes two arguments if they are provided.
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+
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+@<Functions for scripting@>=
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+QScriptValue constructRateOfChange(QScriptContext *context, QScriptEngine *engine)
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+{
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+	int cachetime = 1;
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+	int scaletime = 1;
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+	if(context->argumentCount() > 0)
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+	{
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+		cachetime = argument<int>(0, context);
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+		if(context->argumentCount() > 1)
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+		{
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+			scaletime = argument<int>(1, context);
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+		}
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+	}
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+	QScriptValue object = engine->newQObject(new RateOfChange(cachetime, scaletime));
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+	setRateOfChangeProperties(object, engine);
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+	return object;
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+}
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+
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+void setRateOfChangeProperties(QScriptValue value, QScriptEngine *engine)
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+{
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+	setQObjectProperties(value, engine);
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+}
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+

+ 5
- 2
src/typica.w Dosyayı Görüntüle

@@ -834,6 +834,7 @@ generated file empty.
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 @<LinearSplineInterpolationConfWidget implementation@>@/
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 @<TranslationConfWidget implementation@>@/
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 @<FreeAnnotationConfWidget implementation@>@/
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+@<RateOfChange implementation@>@/
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838 839
 @ A few headers are required for various parts of \pn{}. These allow the use of
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 various Qt modules.
@@ -6743,7 +6744,7 @@ QScriptValue FakeDAQ_newChannel(QScriptContext *context, QScriptEngine *engine)
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 @* The Channel class.
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 \noindent |Channel| is a simple class. It is a subclass of |QObject| so it can
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-use Qt's signals and slots mechanism. Any object that is interested in
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+use Qt'@q'@>s signals and slots mechanism. Any object that is interested in
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 measurements from a channel can connect to the |newData| signal the channel
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 emits. Any number of objects can make this connection and each will receive a
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 copy of the measurement.
@@ -7553,7 +7554,7 @@ constructor = engine->newFunction(constructThresholdDetector);
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 value = engine->newQMetaObject(&ThresholdDetector::staticMetaObject, constructor);
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 engine->globalObject().setProperty("ThresholdDetector", value);
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-@ Implementation. At present I'm not bothering to implement constructor
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+@ Implementation. At present I'@q'@>m not bothering to implement constructor
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 arguments here and am aligning on a fixed point. Another slot method was added
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 to restore adjustability.
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@@ -18232,6 +18233,8 @@ void TranslationConfWidget::updateMatchingColumn(const QString &column)
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 @<Register device configuration widgets@>=
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 app.registerDeviceConfigurationWidget("translation", TranslationConfWidget::staticMetaObject);
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+@i rate.w
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+
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 @** Local changes.
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 \noindent This is the end of \pn{} as distributed by its author. It is expected

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