Python Pandas高级教程之时间处理
简介
时间应该是在数据处理中经常会用到的一种数据类型,除了numpy中datetime64 和 timedelta64 这两种数据类型之外,pandas 还整合了其他python库比如 scikits.timeseries 中的功能。
时间分类
pandas中有四种时间类型:
- date times : 日期和时间,可以带时区。和标准库中的 datetime.datetime 类似。
- time deltas: 绝对持续时间,和 标准库中的 datetime.timedelta 类似。
- time spans: 由时间点及其关联的频率定义的时间跨度。
- date offsets:基于日历计算的时间 和 dateutil.relativedelta.relativedelta 类似。
我们用一张表来表示:
类型 | 标量class | 数组class | pandas数据类型 | 主要创建方法 |
---|---|---|---|---|
date times | timestamp | datetimeindex | datetime64[ns] or datetime64[ns, tz] | to_datetime or date_range |
time deltas | timedelta | timedeltaindex | timedelta64[ns] | to_timedelta or timedelta_range |
time spans | period | periodindex | period[freq] | period or period_range |
date offsets | dateoffset | none | none | dateoffset |
看一个使用的例子:
in [19]: pd.series(range(3), index=pd.date_range("2000", freq="d", periods=3)) out[19]: 2000-01-01 0 2000-01-02 1 2000-01-03 2 freq: d, dtype: int64
看一下上面数据类型的空值:
in [24]: pd.timestamp(pd.nat) out[24]: nat in [25]: pd.timedelta(pd.nat) out[25]: nat in [26]: pd.period(pd.nat) out[26]: nat # equality acts as np.nan would in [27]: pd.nat == pd.nat out[27]: false
timestamp
timestamp 是最基础的时间类型,我们可以这样创建:
in [28]: pd.timestamp(datetime.datetime(2012, 5, 1)) out[28]: timestamp('2012-05-01 00:00:00') in [29]: pd.timestamp("2012-05-01") out[29]: timestamp('2012-05-01 00:00:00') in [30]: pd.timestamp(2012, 5, 1) out[30]: timestamp('2012-05-01 00:00:00')
datetimeindex
timestamp 作为index会自动被转换为datetimeindex:
in [33]: dates = [ ....: pd.timestamp("2012-05-01"), ....: pd.timestamp("2012-05-02"), ....: pd.timestamp("2012-05-03"), ....: ] ....: in [34]: ts = pd.series(np.random.randn(3), dates) in [35]: type(ts.index) out[35]: pandas.core.indexes.datetimes.datetimeindex in [36]: ts.index out[36]: datetimeindex(['2012-05-01', '2012-05-02', '2012-05-03'], dtype='datetime64[ns]', freq=none) in [37]: ts out[37]: 2012-05-01 0.469112 2012-05-02 -0.282863 2012-05-03 -1.509059 dtype: float64
date_range 和 bdate_range
还可以使用 date_range 来创建datetimeindex:
in [74]: start = datetime.datetime(2011, 1, 1) in [75]: end = datetime.datetime(2012, 1, 1) in [76]: index = pd.date_range(start, end) in [77]: index out[77]: datetimeindex(['2011-01-01', '2011-01-02', '2011-01-03', '2011-01-04', '2011-01-05', '2011-01-06', '2011-01-07', '2011-01-08', '2011-01-09', '2011-01-10', ... '2011-12-23', '2011-12-24', '2011-12-25', '2011-12-26', '2011-12-27', '2011-12-28', '2011-12-29', '2011-12-30', '2011-12-31', '2012-01-01'], dtype='datetime64[ns]', length=366, freq='d')
date_range 是日历范围,bdate_range 是工作日范围:
in [78]: index = pd.bdate_range(start, end) in [79]: index out[79]: datetimeindex(['2011-01-03', '2011-01-04', '2011-01-05', '2011-01-06', '2011-01-07', '2011-01-10', '2011-01-11', '2011-01-12', '2011-01-13', '2011-01-14', ... '2011-12-19', '2011-12-20', '2011-12-21', '2011-12-22', '2011-12-23', '2011-12-26', '2011-12-27', '2011-12-28', '2011-12-29', '2011-12-30'], dtype='datetime64[ns]', length=260, freq='b')
两个方法都可以带上 start, end, 和 periods 参数。
in [84]: pd.bdate_range(end=end, periods=20) in [83]: pd.date_range(start, end, freq="w") in [86]: pd.date_range("2018-01-01", "2018-01-05", periods=5)
origin
使用 origin参数,可以修改 datetimeindex 的起点:
in [67]: pd.to_datetime([1, 2, 3], unit="d", origin=pd.timestamp("1960-01-01")) out[67]: datetimeindex(['1960-01-02', '1960-01-03', '1960-01-04'], dtype='datetime64[ns]', freq=none)
默认情况下 origin='unix', 也就是起点是 1970-01-01 00:00:00.
in [68]: pd.to_datetime([1, 2, 3], unit="d") out[68]: datetimeindex(['1970-01-02', '1970-01-03', '1970-01-04'], dtype='datetime64[ns]', freq=none)
格式化
使用format参数可以对时间进行格式化:
in [51]: pd.to_datetime("2010/11/12", format="%y/%m/%d") out[51]: timestamp('2010-11-12 00:00:00') in [52]: pd.to_datetime("12-11-2010 00:00", format="%d-%m-%y %h:%m") out[52]: timestamp('2010-11-12 00:00:00')
period
period 表示的是一个时间跨度,通常和freq一起使用:
in [31]: pd.period("2011-01") out[31]: period('2011-01', 'm') in [32]: pd.period("2012-05", freq="d") out[32]: period('2012-05-01', 'd')
period可以直接进行运算:
in [345]: p = pd.period("2012", freq="a-dec") in [346]: p + 1 out[346]: period('2013', 'a-dec') in [347]: p - 3 out[347]: period('2009', 'a-dec') in [348]: p = pd.period("2012-01", freq="2m") in [349]: p + 2 out[349]: period('2012-05', '2m') in [350]: p - 1 out[350]: period('2011-11', '2m')
注意,period只有具有相同的freq才能进行算数运算。包括 offsets 和 timedelta
in [352]: p = pd.period("2014-07-01 09:00", freq="h") in [353]: p + pd.offsets.hour(2) out[353]: period('2014-07-01 11:00', 'h') in [354]: p + datetime.timedelta(minutes=120) out[354]: period('2014-07-01 11:00', 'h') in [355]: p + np.timedelta64(7200, "s") out[355]: period('2014-07-01 11:00', 'h')
period作为index可以自动被转换为periodindex:
in [38]: periods = [pd.period("2012-01"), pd.period("2012-02"), pd.period("2012-03")] in [39]: ts = pd.series(np.random.randn(3), periods) in [40]: type(ts.index) out[40]: pandas.core.indexes.period.periodindex in [41]: ts.index out[41]: periodindex(['2012-01', '2012-02', '2012-03'], dtype='period[m]', freq='m') in [42]: ts out[42]: 2012-01 -1.135632 2012-02 1.212112 2012-03 -0.173215 freq: m, dtype: float64
可以通过 pd.period_range 方法来创建 periodindex:
in [359]: prng = pd.period_range("1/1/2011", "1/1/2012", freq="m") in [360]: prng out[360]: periodindex(['2011-01', '2011-02', '2011-03', '2011-04', '2011-05', '2011-06', '2011-07', '2011-08', '2011-09', '2011-10', '2011-11', '2011-12', '2012-01'], dtype='period[m]', freq='m')
还可以通过periodindex直接创建:
in [361]: pd.periodindex(["2011-1", "2011-2", "2011-3"], freq="m") out[361]: periodindex(['2011-01', '2011-02', '2011-03'], dtype='period[m]', freq='m')
dateoffset
dateoffset表示的是频率对象。它和timedelta很类似,表示的是一个持续时间,但是有特殊的日历规则。比如timedelta一天肯定是24小时,而在 dateoffset中根据夏令时的不同,一天可能会有23,24或者25小时。
# this particular day contains a day light savings time transition in [144]: ts = pd.timestamp("2016-10-30 00:00:00", tz="europe/helsinki") # respects absolute time in [145]: ts + pd.timedelta(days=1) out[145]: timestamp('2016-10-30 23:00:00+0200', tz='europe/helsinki') # respects calendar time in [146]: ts + pd.dateoffset(days=1) out[146]: timestamp('2016-10-31 00:00:00+0200', tz='europe/helsinki') in [147]: friday = pd.timestamp("2018-01-05") in [148]: friday.day_name() out[148]: 'friday' # add 2 business days (friday --> tuesday) in [149]: two_business_days = 2 * pd.offsets.bday() in [150]: two_business_days.apply(friday) out[150]: timestamp('2018-01-09 00:00:00') in [151]: friday + two_business_days out[151]: timestamp('2018-01-09 00:00:00') in [152]: (friday + two_business_days).day_name() out[152]: 'tuesday'
dateoffsets 和frequency 运算是先关的,看一下可用的date offset 和它相关联的 frequency:
date offset | frequency string | 描述 |
---|---|---|
dateoffset | none | 通用的offset 类 |
bday or businessday | 'b' | 工作日 |
cday or custombusinessday | 'c' | 自定义的工作日 |
week | 'w' | 一周 |
weekofmonth | 'wom' | 每个月的第几周的第几天 |
lastweekofmonth | 'lwom' | 每个月最后一周的第几天 |
monthend | 'm' | 日历月末 |
monthbegin | 'ms' | 日历月初 |
bmonthend or businessmonthend | 'bm' | 营业月底 |
bmonthbegin or businessmonthbegin | 'bms' | 营业月初 |
cbmonthend or custombusinessmonthend | 'cbm' | 自定义营业月底 |
cbmonthbegin or custombusinessmonthbegin | 'cbms' | 自定义营业月初 |
semimonthend | 'sm' | 日历月末的第15天 |
semimonthbegin | 'sms' | 日历月初的第15天 |
quarterend | 'q' | 日历季末 |
quarterbegin | 'qs' | 日历季初 |
bquarterend | 'bq | 工作季末 |
bquarterbegin | 'bqs' | 工作季初 |
fy5253quarter | 'req' | 零售季( 52-53 week) |
yearend | 'a' | 日历年末 |
yearbegin | 'as' or 'bys' | 日历年初 |
byearend | 'ba' | 营业年末 |
byearbegin | 'bas' | 营业年初 |
fy5253 | 're' | 零售年 (aka 52-53 week) |
easter | none | 复活节假期 |
businesshour | 'bh' | business hour |
custombusinesshour | 'cbh' | custom business hour |
day | 'd' | 一天的绝对时间 |
hour | 'h' | 一小时 |
minute | 't' or 'min' | 一分钟 |
second | 's' | 一秒钟 |
milli | 'l' or 'ms' | 一微妙 |
micro | 'u' or 'us' | 一毫秒 |
nano | 'n' | 一纳秒 |
dateoffset还有两个方法 rollforward() 和 rollback() 可以将时间进行移动:
in [153]: ts = pd.timestamp("2018-01-06 00:00:00") in [154]: ts.day_name() out[154]: 'saturday' # businesshour's valid offset dates are monday through friday in [155]: offset = pd.offsets.businesshour(start="09:00") # bring the date to the closest offset date (monday) in [156]: offset.rollforward(ts) out[156]: timestamp('2018-01-08 09:00:00') # date is brought to the closest offset date first and then the hour is added in [157]: ts + offset out[157]: timestamp('2018-01-08 10:00:00')
上面的操作会自动保存小时,分钟等信息,如果想要设置为 00:00:00 , 可以调用normalize() 方法:
in [158]: ts = pd.timestamp("2014-01-01 09:00") in [159]: day = pd.offsets.day() in [160]: day.apply(ts) out[160]: timestamp('2014-01-02 09:00:00') in [161]: day.apply(ts).normalize() out[161]: timestamp('2014-01-02 00:00:00') in [162]: ts = pd.timestamp("2014-01-01 22:00") in [163]: hour = pd.offsets.hour() in [164]: hour.apply(ts) out[164]: timestamp('2014-01-01 23:00:00') in [165]: hour.apply(ts).normalize() out[165]: timestamp('2014-01-01 00:00:00') in [166]: hour.apply(pd.timestamp("2014-01-01 23:30")).normalize() out[166]: timestamp('2014-01-02 00:00:00')
作为index
时间可以作为index,并且作为index的时候会有一些很方便的特性。
可以直接使用时间来获取相应的数据:
in [99]: ts["1/31/2011"] out[99]: 0.11920871129693428 in [100]: ts[datetime.datetime(2011, 12, 25):] out[100]: 2011-12-30 0.56702 freq: bm, dtype: float64 in [101]: ts["10/31/2011":"12/31/2011"] out[101]: 2011-10-31 0.271860 2011-11-30 -0.424972 2011-12-30 0.567020 freq: bm, dtype: float64
获取全年的数据:
in [102]: ts["2011"] out[102]: 2011-01-31 0.119209 2011-02-28 -1.044236 2011-03-31 -0.861849 2011-04-29 -2.104569 2011-05-31 -0.494929 2011-06-30 1.071804 2011-07-29 0.721555 2011-08-31 -0.706771 2011-09-30 -1.039575 2011-10-31 0.271860 2011-11-30 -0.424972 2011-12-30 0.567020 freq: bm, dtype: float64
获取某个月的数据:
in [103]: ts["2011-6"] out[103]: 2011-06-30 1.071804 freq: bm, dtype: float64
df可以接受时间作为loc的参数:
in [105]: dft out[105]: a 2013-01-01 00:00:00 0.276232 2013-01-01 00:01:00 -1.087401 2013-01-01 00:02:00 -0.673690 2013-01-01 00:03:00 0.113648 2013-01-01 00:04:00 -1.478427 ... ... 2013-03-11 10:35:00 -0.747967 2013-03-11 10:36:00 -0.034523 2013-03-11 10:37:00 -0.201754 2013-03-11 10:38:00 -1.509067 2013-03-11 10:39:00 -1.693043 [100000 rows x 1 columns] in [106]: dft.loc["2013"] out[106]: a 2013-01-01 00:00:00 0.276232 2013-01-01 00:01:00 -1.087401 2013-01-01 00:02:00 -0.673690 2013-01-01 00:03:00 0.113648 2013-01-01 00:04:00 -1.478427 ... ... 2013-03-11 10:35:00 -0.747967 2013-03-11 10:36:00 -0.034523 2013-03-11 10:37:00 -0.201754 2013-03-11 10:38:00 -1.509067 2013-03-11 10:39:00 -1.693043 [100000 rows x 1 columns]
时间切片:
in [107]: dft["2013-1":"2013-2"] out[107]: a 2013-01-01 00:00:00 0.276232 2013-01-01 00:01:00 -1.087401 2013-01-01 00:02:00 -0.673690 2013-01-01 00:03:00 0.113648 2013-01-01 00:04:00 -1.478427 ... ... 2013-02-28 23:55:00 0.850929 2013-02-28 23:56:00 0.976712 2013-02-28 23:57:00 -2.693884 2013-02-28 23:58:00 -1.575535 2013-02-28 23:59:00 -1.573517 [84960 rows x 1 columns]
切片和完全匹配
考虑下面的一个精度为分的series对象:
in [120]: series_minute = pd.series( .....: [1, 2, 3], .....: pd.datetimeindex( .....: ["2011-12-31 23:59:00", "2012-01-01 00:00:00", "2012-01-01 00:02:00"] .....: ), .....: ) .....: in [121]: series_minute.index.resolution out[121]: 'minute'
时间精度小于分的话,返回的是一个series对象:
in [122]: series_minute["2011-12-31 23"] out[122]: 2011-12-31 23:59:00 1 dtype: int64
时间精度大于分的话,返回的是一个常量:
in [123]: series_minute["2011-12-31 23:59"] out[123]: 1 in [124]: series_minute["2011-12-31 23:59:00"] out[124]: 1
同样的,如果精度为秒的话,小于秒会返回一个对象,等于秒会返回常量值。
时间序列的操作
shifting
使用shift方法可以让 time series 进行相应的移动:
in [275]: ts = pd.series(range(len(rng)), index=rng) in [276]: ts = ts[:5] in [277]: ts.shift(1) out[277]: 2012-01-01 nan 2012-01-02 0.0 2012-01-03 1.0 freq: d, dtype: float64
通过指定 freq , 可以设置shift的方式:
in [278]: ts.shift(5, freq="d") out[278]: 2012-01-06 0 2012-01-07 1 2012-01-08 2 freq: d, dtype: int64 in [279]: ts.shift(5, freq=pd.offsets.bday()) out[279]: 2012-01-06 0 2012-01-09 1 2012-01-10 2 dtype: int64 in [280]: ts.shift(5, freq="bm") out[280]: 2012-05-31 0 2012-05-31 1 2012-05-31 2 dtype: int64
频率转换
时间序列可以通过调用 asfreq 的方法转换其频率:
in [281]: dr = pd.date_range("1/1/2010", periods=3, freq=3 * pd.offsets.bday()) in [282]: ts = pd.series(np.random.randn(3), index=dr) in [283]: ts out[283]: 2010-01-01 1.494522 2010-01-06 -0.778425 2010-01-11 -0.253355 freq: 3b, dtype: float64 in [284]: ts.asfreq(pd.offsets.bday()) out[284]: 2010-01-01 1.494522 2010-01-04 nan 2010-01-05 nan 2010-01-06 -0.778425 2010-01-07 nan 2010-01-08 nan 2010-01-11 -0.253355 freq: b, dtype: float64
asfreq还可以指定修改频率过后的填充方法:
in [285]: ts.asfreq(pd.offsets.bday(), method="pad") out[285]: 2010-01-01 1.494522 2010-01-04 1.494522 2010-01-05 1.494522 2010-01-06 -0.778425 2010-01-07 -0.778425 2010-01-08 -0.778425 2010-01-11 -0.253355 freq: b, dtype: float64
resampling 重新取样
给定的时间序列可以通过调用resample方法来重新取样:
in [286]: rng = pd.date_range("1/1/2012", periods=100, freq="s") in [287]: ts = pd.series(np.random.randint(0, 500, len(rng)), index=rng) in [288]: ts.resample("5min").sum() out[288]: 2012-01-01 25103 freq: 5t, dtype: int64
resample 可以接受各类统计方法,比如: sum, mean, std, sem, max, min, median, first, last, ohlc。
in [289]: ts.resample("5min").mean() out[289]: 2012-01-01 251.03 freq: 5t, dtype: float64 in [290]: ts.resample("5min").ohlc() out[290]: open high low close 2012-01-01 308 460 9 205 in [291]: ts.resample("5min").max() out[291]: 2012-01-01 460 freq: 5t, dtype: int64
总结
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