Hey, I quite like this! You’re the first person I’ve found that’s thought of fixing the calendar by adopting six-day weeks. I have a very similar personal version, with two main differences:
there’s a leap week instead of a leap day, that way weekdays are always the same without having to skip any and every year has a whole number of weeks (either 61 most years [roughly 7 out of every 8] or 60 on short years [roughly 1 out of every 8])
December includes this leap week and it’s either 30 or 36 days long, depending on the year. I put it at the end of December for the same logic that you put Saturnalia at the end of the year, to not mess with cardinal dates and so that the Xth day of the year is always the same date
I also came to the same conclusion about workweeks. With two-day weekends, the Gregorian calendar has 71 % of workdays but the new calendar only has 67 %. On a thirty-day month this means 20 workdays instead of 21,5
Only in eight year chunks. By year seven there is more unalignment than there was in year one, but it goes back to normal on year eight. Same thing as with leap days, just a slightly bigger scale.
In fact, with current rules, [the shift in the regular Gregorian calendar becomes quite big when considering 100-year and 400-year cycles](File:Gregoriancalendarleap_solstice.svg). In theory, a leap week calendar with new and updated rules could have a very comparable if not a smaller average deviation from the true solar date, though I haven’t ran the precise calculations
Ok, so, first, let me say that while I’m enthusiastic about the concept, I understand it’s entirely theoretical. We can’t even get US civilians to adopt metric, FFS. Just a caveat, lest anyone wander by and overhear us.
That said, I did spend some cycles trying to see it it would be possibly to line up a lunar and solar calendar, and it’s not. And it isn’t nearly as important as it used to be. It would still have been nice.
So if you do run calculations, I’d like to see them.
Here they are! Orange represents my Leapweek calendar and blue is Gregorian. The Y-axis is deviation from the tropical year and the X-axis is the year number. It’s a 19200-year cycle to allow for both Gregorian and Leapweek to do entire iterations of their 400-year and 768-year cycles, respectively.
The Gregorian rules are, as you already know: if a year is divisible by 4, it is a leap year; unless it is divisible by 100, when it is a common year; unless it is also divisible by 400, in which case it is actually a leap year.
My Leapweek rules are: years divisible by 8, are leap (short, with 360 days instead of the usual 366) years, as are years divisible by 768 (after subtracting 4 so as not to clash with years divisible by 8). Just two rules as opposed to Gregorian’s three, but they result in almost perfect correction: it takes 625 000 years to fall out of sync by 1 day, as opposed to Gregorian’s 3 216 years for the same amount)
The catch is that Leapweek falls out of sync by up to 5½ days either way in between 768-year cycles, and up to 2½ days either way in between 8-year cycles. But they average out.
About the lunisolar I’m afraid to say that I ran into the same issue. Lunations are a very inconvenient duration to try and fit into neat solar days and months.
I wish it weren’t as theoretical, because I really like this calendar, but yea. It’s one of those things that will be impossible to change even though there’s arguably better options. It’s too arbitrary yet too essential and it goes in the same box as the metric second/minute/hour, the dozenal system and the Holocene calendar.
Here’s a challenge though: try and devise a Martian calendar! That one is not standardised yet. I had good fun trying to match the Martian sol and year to metric units of time and maybe giving some serious use to the kilosecond, megasecond and gigasecond
As an extra, here’s a 1000-year version of the graph at the start of the reply, with the current year 12 025 of the Holocene calendar :^) in the middle
This is fantastic. I’m going to have to spend more time with it.
Since we’re discussing timescales over which there’s a not insignificant chance something radical will happen to society, there’s also the fact that the day is getting longer by 2ms every hundred years. If you’re scheduling out 625,000 years, that’s 12-some seconds by the end, compounded - 6 extra seconds every day by the 312,000th year, etc.
Hey, I quite like this! You’re the first person I’ve found that’s thought of fixing the calendar by adopting six-day weeks. I have a very similar personal version, with two main differences:
I also came to the same conclusion about workweeks. With two-day weekends, the Gregorian calendar has 71 % of workdays but the new calendar only has 67 %. On a thirty-day month this means 20 workdays instead of 21,5
How does that work, with the leap week? Doesn’t the year drift out of alignment with the solar cycle?
Only in eight year chunks. By year seven there is more unalignment than there was in year one, but it goes back to normal on year eight. Same thing as with leap days, just a slightly bigger scale.
In fact, with current rules, [the shift in the regular Gregorian calendar becomes quite big when considering 100-year and 400-year cycles](File:Gregoriancalendarleap_solstice.svg). In theory, a leap week calendar with new and updated rules could have a very comparable if not a smaller average deviation from the true solar date, though I haven’t ran the precise calculations
Ok, so, first, let me say that while I’m enthusiastic about the concept, I understand it’s entirely theoretical. We can’t even get US civilians to adopt metric, FFS. Just a caveat, lest anyone wander by and overhear us.
That said, I did spend some cycles trying to see it it would be possibly to line up a lunar and solar calendar, and it’s not. And it isn’t nearly as important as it used to be. It would still have been nice.
So if you do run calculations, I’d like to see them.
Here they are! Orange represents my Leapweek calendar and blue is Gregorian. The Y-axis is deviation from the tropical year and the X-axis is the year number. It’s a 19200-year cycle to allow for both Gregorian and Leapweek to do entire iterations of their 400-year and 768-year cycles, respectively.
The Gregorian rules are, as you already know: if a year is divisible by 4, it is a leap year; unless it is divisible by 100, when it is a common year; unless it is also divisible by 400, in which case it is actually a leap year.
My Leapweek rules are: years divisible by 8, are leap (short, with 360 days instead of the usual 366) years, as are years divisible by 768 (after subtracting 4 so as not to clash with years divisible by 8). Just two rules as opposed to Gregorian’s three, but they result in almost perfect correction: it takes 625 000 years to fall out of sync by 1 day, as opposed to Gregorian’s 3 216 years for the same amount)
The catch is that Leapweek falls out of sync by up to 5½ days either way in between 768-year cycles, and up to 2½ days either way in between 8-year cycles. But they average out.
About the lunisolar I’m afraid to say that I ran into the same issue. Lunations are a very inconvenient duration to try and fit into neat solar days and months.
I wish it weren’t as theoretical, because I really like this calendar, but yea. It’s one of those things that will be impossible to change even though there’s arguably better options. It’s too arbitrary yet too essential and it goes in the same box as the metric second/minute/hour, the dozenal system and the Holocene calendar.
Here’s a challenge though: try and devise a Martian calendar! That one is not standardised yet. I had good fun trying to match the Martian sol and year to metric units of time and maybe giving some serious use to the kilosecond, megasecond and gigasecond
As an extra, here’s a 1000-year version of the graph at the start of the reply, with the current year 12 025 of the Holocene calendar :^) in the middle
This is fantastic. I’m going to have to spend more time with it.
Since we’re discussing timescales over which there’s a not insignificant chance something radical will happen to society, there’s also the fact that the day is getting longer by 2ms every hundred years. If you’re scheduling out 625,000 years, that’s 12-some seconds by the end, compounded - 6 extra seconds every day by the 312,000th year, etc.