kopia lustrzana https://github.com/peterhinch/micropython-samples
astronomy: Add moonphase.py.
rodzic
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@ -10,29 +10,36 @@
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2.2 [Methods](./README.md#22-methods)
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2.3 [Effect of local time](./README.md#23-effect-of-local-time)
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2.4 [Continuously running applications](./README.md#24-continuously-running-applications)
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3. [The moonphase function](./README.md#3-the-moonphase-function)
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4. [Utility functions](./README.md#4-utility-functions)
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5. [Demo script](./README.md#5-demo-script)
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6. [Scheduling events](./README.md#6-scheduling-events)
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3. [Utility functions](./README.md#3-utility-functions)
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4. [Demo script](./README.md#4-demo-script)
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5. [Scheduling events](./README.md#5-scheduling-events)
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6. [The moonphase module](./README.md#6-the-moonphase-module)
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6.1 [Constructor](./README.md#61-constructor)
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6.2 [Methods](./README.md#62-methods)
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6.3 [Usage examples](./README.md#63-usage-examples)
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6.4 [DST](./README.md#64-dst) Daylight savings time.
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7. [Performance and accuracy](./README.md#7-performance-and-accuracy)
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7.1 [RiSet class](./README.md#71-riset-class)
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7.2 [moonphase class](./README.md#72-moonphase-class)
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# 1. Overview
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This module enables sun and moon rise and set times to be determined at any
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geographical location. Times are in seconds from midnight and refer to any
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event in a 24 hour period starting at midnight. The midnight datum is defined in
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local time. The start is a day specified as the current day plus an offset in
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days.
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The `sun_moon` module enables sun and moon rise and set times to be determined
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at any geographical location. Times are in seconds from midnight and refer to
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any event in a 24 hour period starting at midnight. The midnight datum is
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defined in local time. The start is a day specified as the current day plus an
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offset in days. It can also compute Civil, Nautical or Astronomical twilight
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times.
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It can also compute Civil, Nautical or Astronomical twilight times. A
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`moonphase` function is also provided enabling the moon phase to be determined
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for any date.
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The `moonphase` module enables the moon phase to be determined for any date, and
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the dates and times of lunar quarters to be calculated.
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Caveat. I am not an astronomer. If there are errors in the fundamental
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algorithms I am unlikely to be able to offer an opinion, still less a fix.
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The code is currently under development but I don't anticipate breaking changes
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to the API.
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The `moonphase` module is currently under development: API changes are possible.
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Moon phase options have been removed from `sun_moon` because accuracy was poor.
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## 1.1 Applications
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@ -43,6 +50,8 @@ lunar clocks such as this one - the "lunartick":
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## 1.2 Licensing and acknowledgements
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#### sun_moon.py
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Some code was ported from C/C++ as presented in "Astronomy on the Personal
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Computer" by Montenbruck and Pfleger, with mathematical improvements contributed
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by Marcus Mendenhall and Raul Kompaß. I (Peter Hinch) performed the port and
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@ -56,6 +65,11 @@ source. I have not spotted any restrictions on use in the book. I am not a
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lawyer; I have no idea of the legal status of code based on sourcecode in a
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published work.
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#### moonphase.py
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This was derived from unrestricted public sources and is released under the MIT
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licence.
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## 1.3 Installation
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Installation copies files from the `astronomy` directory to a directory
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@ -146,11 +160,8 @@ instance.
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horizon.
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* `has_risen(sun: bool)->bool` Returns `True` if the selected object has risen.
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* `has_set(sun: bool)->bool` Returns `True` if the selected object has set.
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* `moonphase()->float` Return current phase: 0.0 <= result < 1.0. 0.0 is new
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moon, 0.5 is full. See [section 3](./README.md#3-the-moonphase-function) for
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observations about this.
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* `set_lto(t)` Set local time offset `LTO` in hours relative to UTC. Primarily
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intended for daylight saving time. The value is checked to ensure
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intended for system longitude. The value is checked to ensure
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`-15.0 < lto < 15.0`. See [section 2.3](./README.md#23-effect-of-local-time).
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The return value of the rise and set method is determined by the `variant` arg.
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@ -223,28 +234,14 @@ bad idea. It is usually best to run winter time all year round. Where a DST
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change occurs, the `RiSet.set_lto()` method should be run to ensure that `RiSet`
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operates in current local time.
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# 3. The moonphase function
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This is a simple function whose provenance is uncertain. It appears to produce
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valid results but I plan to implement a better solution.
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Args:
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* `year: int` 4-digit year
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* `month: int` 1..12
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* `day: int` Day of month 1..31
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* `hour: int` 0..23
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Return value:
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A float in range 0.0 <= result < 1.0, 0 being new moon, 0.5 being full moon.
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# 4. Utility functions
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# 3. Utility functions
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`now_days() -> int` Returns the current time as days since the platform epoch.
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`abs_to_rel_days(days: int) -> int` Takes a number of days since the Unix epoch
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(1970,1,1) and returns a number of days relative to the current date. Platform
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independent. This facilitates testing with pre-determined target dates.
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# 5. Demo script
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# 4. Demo script
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This produces output for the fixed date 4th Dec 2023 at three geographical
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locations. It can therefore be run on platforms where the system time is wrong.
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@ -290,7 +287,7 @@ Maximum error 0. Expect 0 on 64-bit platform, 30s on 32-bit
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```
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Code comments show times retrieved from `timeanddate.com`.
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# 6. Scheduling events
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# 5. Scheduling events
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A likely use case is to enable events to be timed relative to sunrise and set.
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In simple cases this can be done with `asyncio`. This will execute a payload at
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@ -386,9 +383,108 @@ try:
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finally:
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_ = asyncio.new_event_loop()
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```
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# 6. The moonphase module
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This contains a single class `MoonPhase`. The term "machine time" below refers
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to the time reported by the MicroPython `time` module. The "local time offset"
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(LTO) passed to the constructor specifies the difference between machine time
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and UTC based on system longitude. "Daylight saving time" (DST) allows reported
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times to be offset to compensate for DST. Internally phases are calculated in
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UTC, but where times are output they are adjusted for LTO and DST.
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It is recommended that the machine clock is not adjusted for DST because large
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changes can play havoc with program timing as described above. To accommodate
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DST, a `dst` function can be provided to the constructor. The module uses this
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to adjust reported times.
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A `MoonPhase` instance has a time `datum`, which defaults to the instantiation
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time. Phases are calculated with respect to this datum. It may be changed using
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`.set_day` to enable future and past phases to be determined or to enable long
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running applications to track time.
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## 6.1 Constructor
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* `lto:float=0, dst = lambda x: x` Local time offset in hours to UTC (-ve is
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West); the value is checked to ensure `-15 < lto < 15`. `dst` is an optional
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user defined function for Daylight Saving Time (DST). See
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[section 6.4](./README.md#64-dst)
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## 6.2 Methods
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* `quarter(q: int, text: bool = True)` Return the time of a given quarter. Five
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quarters are calculated around the instance datum. By default the time
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is last midnight machine time with an optional offset in days `doff` added. The
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`quarter` arg specifies the quarter with 0 and 4 being new moons and quarter 2
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being full. The `text` arg determines how the value is returned: as text or as
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`int` is secs from the machine epoch. Results are adjusted for DST if a `dst`
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function is provided to the constructor.
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* `phase() -> float)` Returns moon phase where 0.0 <= phase < 1.0 with 0.5 being
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full moon. The phase is that pertaining to the datum.
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* `nextphase(, text: bool = True)` This is a generator function. Each iteration
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of the generator returns three values: the phase number, the lunation number and
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the datetime of the phase. The `text` arg is as per `.quarter()`, defining the
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format of the datetime.
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* `set_day(doff: float = 0)` Set the `MoonPhase` datum time to machine time plus
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an offset in days: this may include a fractional part if `.phase()` is required
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to produce a time-precise value. The five quarters are calculated for the
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lunation including the midnight at the start of the specified day.
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* `set_lto(t:float)` Redefine the local time offset, `t` being in hours as
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per the constructor arg.
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* `datum(text: bool = True)` Returns the current datum.
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## 6.3 Usage examples
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```python
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from moonphase import MoonPhase
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mp = MoonPhase() # datum is midnight last night
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print(f"Full moon, current lunation {mp.quarter(2)}")
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mp.set_day(0.5) # Adjust datum to noon today machine time
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print(f"Phase at Noon {mp.phase()}")
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mp.set_day(182) # Set datum ahead 6 months
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print(f"Lunation 1st new moon: {mp.quarter(0)}, 2nd new moon: {mp.quarter(4)}")
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mp.set_day(0) # Reset datum to today
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n = mp.nextphase() # Instantiate generator
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for _ in range(8):
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print(next(n))
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```
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## 6.4 DST
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Daylight saving time depends on country and geographic location, and there is no
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built-in MicroPython support. The moonphase module supports DST via an optional
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user supplied function. DST does not affect the calculation of quarters or phase
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which is based on the machine clock. If the machine clock runs at a fixed offset
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to UTC (which is recommended), a DST function can be used to enable reported
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results to reflect local time.
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A DST function takes as input a time measured in seconds since the machine epoch
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(as returned by `time.time()`) and returns that number adjusted for local time.
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The following example is for UK time, which adds one hour at 2:00 on the last
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Sunday in March, reverting to winter time at 2:00 on the last Sunday in October.
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```python
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def uk_dst(secs_epoch: int): # Change in March (3) and Oct (10)
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t = time.gmtime(secs_epoch)
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month = t[1]
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mday = t[2]
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wday = t[6]
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winter = secs_epoch
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summer = secs_epoch + 3600 # +1hr
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if month in (1, 2, 11, 12): # Simple cases: depend only on month
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return winter
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if not month in (3, 10):
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return summer # +1 hr
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# We are in March or October. Find the day in month of last Sunday.
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ld = (wday + 31 - mday) % 7 # weekday of 31st.
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lsun = 31 - (1 + ld) % 7
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thresh = time.mktime((t[0], month, lsun, 2, 0, 0, 6, 0))
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return summer if ((secs_epoch >= thresh) ^ (month == 10)) else winter
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```
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# 7. Performance and accuracy
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## 7.1 RiSet class
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A recalculation is triggered whenever the 24 hour local time window is changed,
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such as calling `.set_day()` where the stored date changes. Normally two days of
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data are calculated, except where the local time is UTC where only one day is
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@ -401,7 +497,6 @@ checked values corresponded with data computed on a platform with 64 bit
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floating point unit. The loss of precision from using a 32 bit FPU was no more
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than 3s.
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The lunar phase calculation is poor. It is adequate for displaying a phase icon
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or adjusting a pointer, but not good enough for predicting lunar quarters.
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## 7.2 MoonPhase class
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I plan to improve this, but it may be via a separate module.
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TODO
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@ -0,0 +1,228 @@
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# moonphase.py Calculate lunar phases
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# Source Tech\ Notes/Astronomy/astro_references/moontool.c
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# The information for this was drawn from public domain sources including C code
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# written by John Walker and Ron Hitchens in 1987-88 and released with the "licence"
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# Do what thou wilt shall be the whole of the law".
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# Uses Python arbitrary length integers to maintain accuracy on platforms with
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# 32-bit floating point.
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# Copyright (c) Peter Hinch 2023 Released under the MIT license.
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# Exports calc_phases()
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from math import radians, sin, cos, floor
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import time
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import array
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SYNMONTH = 29.53058868 # Synodic month (new Moon to new Moon)
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# MEANPHASE -- Calculates time of the mean new Moon for a given base date.
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# This argument K to this function is the precomputed synodic month index, given by:
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# K = (year - 1900) * 12.3685
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# where year is expressed as a year and fractional year.
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# sdate is days from 1900 January 0.5. Returns days from 1900 January 0.5
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def meanphase(sdate: float, k: int) -> float:
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# Time in Julian centuries from 1900 January 0.5
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t = sdate / 36525
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t2 = t * t # Square for frequent use
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t3 = t2 * t # Cube for frequent use
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nt1 = 0.75933 + SYNMONTH * k + 0.0001178 * t2 - 0.000000155 * t3
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return nt1 + 0.00033 * sin(radians(166.56 + 132.87 * t - 0.009173 * t2))
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# TRUEPHASE -- Given a K value used to determine the mean phase of the new moon,
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# and a phase no. (0..3), return the true, corrected phase time
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# as integer Julian seconds.
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def truephase(k: int, phi: int) -> int:
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k += (0, 0.25, 0.5, 0.75)[phi] # Add phase to new moon time
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t = k / 1236.85 # Time in Julian centuries from 1900 January 0.5
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t2 = t * t # Square for frequent use
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t3 = t2 * t # Cube for frequent use
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# Sun's mean anomaly
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m = 359.2242 + 29.10535608 * k - 0.0000333 * t2 - 0.00000347 * t3
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# Moon's mean anomaly
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mprime = 306.0253 + 385.81691806 * k + 0.0107306 * t2 + 0.00001236 * t3
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# Moon's argument of latitude
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f = 21.2964 + 390.67050646 * k - 0.0016528 * t2 - 0.00000239 * t3
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if phi in (0, 2): # Corrections for New and Full Moon
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pt = (0.1734 - 0.000393 * t) * sin(radians(m))
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pt += 0.0021 * sin(radians(2 * m))
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pt -= 0.4068 * sin(radians(mprime))
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pt += 0.0161 * sin(radians(2 * mprime))
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pt -= 0.0004 * sin(radians(3 * mprime))
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pt += 0.0104 * sin(radians(2 * f))
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pt -= 0.0051 * sin(radians(m + mprime))
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pt -= 0.0074 * sin(radians(m - mprime))
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pt += 0.0004 * sin(radians(2 * f + m))
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pt -= 0.0004 * sin(radians(2 * f - m))
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pt -= 0.0006 * sin(radians(2 * f + mprime))
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pt += 0.0010 * sin(radians(2 * f - mprime))
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pt += 0.0005 * sin(radians(m + 2 * mprime))
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else: # First or last quarter
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pt = (0.1721 - 0.0004 * t) * sin(radians(m))
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pt += 0.0021 * sin(radians(2 * m))
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pt -= 0.6280 * sin(radians(mprime))
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pt += 0.0089 * sin(radians(2 * mprime))
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pt -= 0.0004 * sin(radians(3 * mprime))
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pt += 0.0079 * sin(radians(2 * f))
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pt -= 0.0119 * sin(radians(m + mprime))
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pt -= 0.0047 * sin(radians(m - mprime))
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pt += 0.0003 * sin(radians(2 * f + m))
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pt -= 0.0004 * sin(radians(2 * f - m))
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pt -= 0.0006 * sin(radians(2 * f + mprime))
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pt += 0.0021 * sin(radians(2 * f - mprime))
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pt += 0.0003 * sin(radians(m + 2 * mprime))
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pt += 0.0004 * sin(radians(m - 2 * mprime))
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pt -= 0.0003 * sin(radians(2 * m + mprime))
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if phi < 2: # First quarter correction
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pt += 0.0028 - 0.0004 * cos(radians(m)) + 0.0003 * cos(radians(mprime))
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else: # Last quarter correction
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pt += -0.0028 + 0.0004 * cos(radians(m)) - 0.0003 * cos(radians(mprime))
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pt = round(pt * 86400) # Integer seconds from here
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pt += round(2_953_058_868 * 864 * k) // 1000_000 # round(SYNMONTH * k * 86400)
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qq = 0.0001178 * t2 - 0.000000155 * t3
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qq += 0.00033 * sin(radians(166.56 + 132.87 * t - 0.009173 * t2))
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pt += round(qq * 86400) # qq amounts to 2s
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return pt + 208_657_793_606
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def dt_to_text(tim): # Convert a time to text
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t = time.localtime(tim)
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return f"{t[2]:02}/{t[1]:02}/{t[0]:4} {t[3]:02}:{t[4]:02}:{t[5]:02}"
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class MoonPhase:
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verbose = True
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def __init__(self, lto: float = 0, dst=lambda x: x):
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self.lto_s = self._check_lto(lto) # -15 < lto < 15
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# local time = UTC + lto .lto_s = offset in secs
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self.dst = dst
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# Datetimes in secs since hardware epoch based on UTC
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# With epoch 1970 this could need long ints.
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self.phases = array.array("q", (0,) * 5)
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# Calculate Julian date of machine epoch
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# Multiply by 100 to avoid fraction
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jepoch = 244058750 # Julian date of Unix epoch (1st Jan 1970) * 100
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if time.gmtime(0)[0] == 2000: # Machine epoch
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jepoch += 1095700
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jepoch *= 864 # Seconds from epoch
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self.jepoch = jepoch
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self.secs = 0 # Time of calling .set_day in secs UTC
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self.set_day() # Populate array and .secs
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if MoonPhase.verbose:
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print(f"Machine time: {dt_to_text(time.time())}")
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MoonPhase.verbose = False
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# Take offset in days from today, return time of last midnight in secs from machine epoch
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# Take time of last midnight machine time in secs since machine epoch. Add a
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# passed offset in days. Convert to UTC using LTO. The returned value is as
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# if the hardware clock were running UTC.
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def _midnight(self, doff: float = 0): # Midnight last night + days offset (UTC)
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tl = round((time.time() // 86400 + doff) * 86400) # Target in local time
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return tl - self.lto_s
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def set_lto(self, t: float): # Update the offset from UTC
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self.lto_s = self._check_lto(t) # Localtime offset in secs
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def set_day(self, doff: float = 0):
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self.secs = round(time.time() + doff * 86400 - self.lto_s)
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start = self._midnight(doff) # Phases are calculated around this time (UTC)
|
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self._populate(start) # Immediate return if .phases already OK
|
||||
|
||||
def datum(self, text: bool = True):
|
||||
t = self.secs + self.lto_s
|
||||
return dt_to_text(t) if text else t
|
||||
|
||||
def quarter(self, q: int, text: bool = True):
|
||||
if not 0 <= q <= 4:
|
||||
raise ValueError("Quarter nos must be from 0 to 4.")
|
||||
tutc = self.phases[q] # Time of phase in secs UTC
|
||||
# Adjust time: t is machine time in secs since machine epoch
|
||||
t = self.dst(tutc + self.lto_s) # UTC secs from hardware epoch -> local time
|
||||
return dt_to_text(t) if text else t # Secs since machine epoch
|
||||
|
||||
# Return moon phase as 0.0 <= n < 1.0 by defaut for current datetime.
|
||||
def phase(self) -> float: # doff: days offset with optional fraction
|
||||
t = self.secs # As set by .set_day()
|
||||
if not (self.phases[0] <= t <= self.phases[4]): # set_day was not called
|
||||
self.set_day() # Assume today
|
||||
prev = self.phases[0]
|
||||
for n, phi in enumerate(self.phases):
|
||||
if phi > t:
|
||||
break # phi is upcoming phase time
|
||||
prev = phi # Last phase before now
|
||||
if prev == phi: # Day is day of new moon: use synodic month/4
|
||||
r = (t - prev) * 0.25 / 637860.715488
|
||||
if r < 0:
|
||||
r = 1 - r
|
||||
else:
|
||||
r = (n - 1) * 0.25 + (t - prev) * 0.25 / (phi - prev)
|
||||
return min(r, 0.999999) # Rare pathological results where r slightly > 1.0
|
||||
|
||||
def _next_lunation(self): # Use approx time of next full moon to advance
|
||||
self._populate(round(self.phases[2] + SYNMONTH * 86400))
|
||||
|
||||
# toff: days offset with optional fraction
|
||||
def nextphase(self, text: bool = True):
|
||||
n = 0
|
||||
lun = 0 # Skip historic quarters
|
||||
while True:
|
||||
yield n, lun, self.quarter(n, text)
|
||||
n += 1
|
||||
n %= 4
|
||||
if n == 0:
|
||||
self._next_lunation()
|
||||
lun += 1
|
||||
|
||||
def _check_lto(self, lto: float) -> int:
|
||||
if not -15 < lto < 15:
|
||||
raise ValueError("Invalid local time offset.")
|
||||
return round(lto * 3600)
|
||||
|
||||
# Populate the phase array. Fast return if phases are alrady correct.
|
||||
# Find time of phases of the moon which surround the passed datetime.
|
||||
# Five phases are found, starting and ending with the new moons which bound
|
||||
# the specified lunation.
|
||||
# Passed time, and the result in .phases, are seconds since hardware epoch
|
||||
# adjusted for UTC: i.e. as if the RTC were running UTC rather than local time.
|
||||
def _populate(self, t: int):
|
||||
if self.phases[0] < t < self.phases[4]:
|
||||
return # Nothing to do
|
||||
# Return days since Jan 0.5 1900 as a float. Returns same value on 32 and 64 bits
|
||||
def jd1900(t: int) -> float:
|
||||
y, m, mday = time.localtime(t)[:3]
|
||||
if m <= 2:
|
||||
m += 12
|
||||
y -= 1
|
||||
b = round(y / 400 - y / 100 + y / 4)
|
||||
mjm = 365 * y - 679004 + b + int(30.6001 * (m + 1)) + mday
|
||||
return mjm - 15019.5
|
||||
|
||||
sdate: float = jd1900(t) # Days since 1900 January 0.5
|
||||
adate: float = sdate - 45
|
||||
yy, mm, dd = time.localtime(t)[:3]
|
||||
k1: int = floor((yy + ((mm - 1) * (1.0 / 12.0)) - 1900) * 12.3685) # 365.25/SYNMONTH
|
||||
adate = meanphase(adate, k1) # Find new moon well before current date
|
||||
nt1: float = adate
|
||||
while True:
|
||||
adate += SYNMONTH # For each lunar month
|
||||
k2: int = k1 + 1
|
||||
nt2: float = meanphase(adate, k2)
|
||||
if nt1 <= sdate and nt2 > sdate:
|
||||
break
|
||||
nt1 = nt2
|
||||
k1 = k2
|
||||
# k is integer days since start of 1900, being the lunation number
|
||||
# 1533, 1534 on both platforms.
|
||||
for n, k in enumerate((k1, k1, k1, k1, k2)):
|
||||
phi: int = truephase(k, n % 4) # Args lunation no., phase no. 0..3
|
||||
self.phases[n] = phi - self.jepoch # Julian datetime to secs since hardware epoch
|
||||
# Datetimes in secs since hardware epoch based on UTC
|
|
@ -1,7 +1,8 @@
|
|||
{
|
||||
"urls": [
|
||||
["sched/sun_moon.py", "github:peterhinch/micropython-samples/astronomy/sun_moon.py"],
|
||||
["sched/sun_moon_test.py", "github:peterhinch/micropython-samples/astronomy/sun_moon_test.py"]
|
||||
["sched/sun_moon_test.py", "github:peterhinch/micropython-samples/astronomy/sun_moon_test.py"],
|
||||
["sched/moonphase.py", "github:peterhinch/micropython-samples/astronomy/moonphase.py"]
|
||||
],
|
||||
"version": "0.1"
|
||||
}
|
||||
|
|
|
@ -12,6 +12,7 @@
|
|||
# Raul Kompaß perfomed major simplification of the maths for deriving rise and
|
||||
# set_times with improvements in precision with 32-bit floats.
|
||||
|
||||
# Moon phase now in separate module
|
||||
|
||||
import time
|
||||
from math import sin, cos, sqrt, fabs, atan, radians, floor, pi
|
||||
|
@ -103,23 +104,6 @@ def to_int(x):
|
|||
return None if x is None else round(x)
|
||||
|
||||
|
||||
# Approximate moon phase in range 0.0..1.0 0.0 is new moon, 0.5 full moon
|
||||
# Provenance of this cde is uncertain.
|
||||
def moonphase(year, month, day, hour):
|
||||
fty = year - floor((12.0 - month) / 10.0)
|
||||
itm = month + 9
|
||||
if itm >= 12:
|
||||
itm -= 12
|
||||
term1 = floor(365.25 * (fty + 4712))
|
||||
term2 = floor(30.6 * itm + 0.5)
|
||||
term3 = floor(floor((fty / 100) + 49) * 0.75) - 38
|
||||
tmp = term1 + term2 + day + 59 + hour / 24.0
|
||||
if tmp > 2299160.0:
|
||||
tmp = tmp - term3
|
||||
phi = (tmp - 2451550.1) / 29.530588853 # 29.530588853 is length of lunar cycle (days)
|
||||
return phi % 1
|
||||
|
||||
|
||||
def minisun(t):
|
||||
# Output sin(dec), cos(dec), ra
|
||||
# returns the ra and dec of the Sun
|
||||
|
@ -231,7 +215,6 @@ class RiSet:
|
|||
# time.time() assumes MicroPython clock is set to local time
|
||||
self._t0 = ((round(time.time()) + day * spd) // spd) * spd
|
||||
t = time.gmtime(time.time() + day * spd)
|
||||
self._phase = moonphase(*t[:4])
|
||||
self.update(mjd) # Recalculate rise and set times
|
||||
return self # Allow r.set_day().sunrise()
|
||||
|
||||
|
@ -255,9 +238,6 @@ class RiSet:
|
|||
def tend(self, variant: int = 0):
|
||||
return self._format(self._times[5], variant)
|
||||
|
||||
def moonphase(self) -> float:
|
||||
return self._phase
|
||||
|
||||
def set_lto(self, t): # Update the offset from UTC
|
||||
self.check_lto(t) # No need to recalc beause date is unchanged
|
||||
self.lto = round(t * 3600) # Localtime offset in secs
|
||||
|
|
Ładowanie…
Reference in New Issue