public class AbsoluteDate extends Object implements TimeStamped, TimeShiftable<AbsoluteDate>, Comparable<AbsoluteDate>, Serializable
Instances of this class are considered to be absolute in the sense
that each one represent the occurrence of some event and can be compared
to other instances or located in any time scale
. In
other words the different locations of an event with respect to two different
time scales (say TAI
and UTC
for example) are
simply different perspective related to a single object. Only one
AbsoluteDate
instance is needed, both representations being available
from this single instance by specifying the time scales as parameter when calling
the ad-hoc methods.
Since an instance is not bound to a specific time-scale, all methods related to the location of the date within some time scale require to provide the time scale as an argument. It is therefore possible to define a date in one time scale and to use it in another one. An example of such use is to read a date from a file in UTC and write it in another file in TAI. This can be done as follows:
DateTimeComponents utcComponents = readNextDate(); AbsoluteDate date = new AbsoluteDate(utcComponents, TimeScalesFactory.getUTC()); writeNextDate(date.getComponents(TimeScalesFactory.getTAI()));
Two complementary views are available:
location view (mainly for input/output or conversions)
locations represent the coordinate of one event with respect to a
time scale
. The related methods are AbsoluteDate(DateComponents, TimeComponents, TimeScale)
, AbsoluteDate(int, int, int, int, int, double, TimeScale)
, AbsoluteDate(int, int, int, TimeScale)
, AbsoluteDate(Date,
TimeScale)
, parseCCSDSCalendarSegmentedTimeCode(byte, byte[])
,
toDate(TimeScale)
, toString(timeScale)
,
toString()
, and timeScalesOffset(org.orekit.time.TimeScale, org.orekit.time.TimeScale)
.
offset view (mainly for physical computation)
offsets represent either the flow of time between two events
(two instances of the class) or durations. They are counted in seconds,
are continuous and could be measured using only a virtually perfect stopwatch.
The related methods are AbsoluteDate(AbsoluteDate, double)
,
parseCCSDSUnsegmentedTimeCode(byte, byte, byte[], AbsoluteDate)
,
parseCCSDSDaySegmentedTimeCode(byte, byte[], DateComponents)
,
durationFrom(AbsoluteDate)
, compareTo(AbsoluteDate)
, equals(Object)
and hashCode()
.
A few reference epochs which are commonly used in space systems have been defined. These
epochs can be used as the basis for offset computation. The supported epochs are:
JULIAN_EPOCH
, MODIFIED_JULIAN_EPOCH
, FIFTIES_EPOCH
,
CCSDS_EPOCH
, GALILEO_EPOCH
, GPS_EPOCH
, QZSS_EPOCH
J2000_EPOCH
, JAVA_EPOCH
.
There are also two factory methods createJulianEpoch(double)
and createBesselianEpoch(double)
that can be used to compute other reference
epochs like J1900.0 or B1950.0.
In addition to these reference epochs, two other constants are defined for convenience:
PAST_INFINITY
and FUTURE_INFINITY
, which can be used either as dummy
dates when a date is not yet initialized, or for initialization of loops searching for
a min or max date.
Instances of the AbsoluteDate
class are guaranteed to be immutable.
TimeScale
,
TimeStamped
,
ChronologicalComparator
,
Serialized FormModifier and Type | Field and Description |
---|---|
static AbsoluteDate |
BEIDOU_EPOCH
Reference epoch for BeiDou weeks: 2006-01-01T00:00:00 UTC.
|
static AbsoluteDate |
CCSDS_EPOCH
Reference epoch for CCSDS Time Code Format (CCSDS 301.0-B-4):
1958-01-01T00:00:00 International Atomic Time (not UTC).
|
static AbsoluteDate |
FIFTIES_EPOCH
Reference epoch for 1950 dates: 1950-01-01T00:00:00 Terrestrial Time.
|
static AbsoluteDate |
FUTURE_INFINITY
Dummy date at infinity in the future direction.
|
static AbsoluteDate |
GALILEO_EPOCH
Reference epoch for Galileo System Time: 1999-08-22T00:00:00 GST.
|
static AbsoluteDate |
GLONASS_EPOCH
Reference epoch for GLONASS four-year interval number: 1996-01-01T00:00:00 GLONASS time.
|
static AbsoluteDate |
GPS_EPOCH
Reference epoch for GPS weeks: 1980-01-06T00:00:00 GPS time.
|
static AbsoluteDate |
J2000_EPOCH
J2000.0 Reference epoch: 2000-01-01T12:00:00 Terrestrial Time (not UTC).
|
static AbsoluteDate |
JAVA_EPOCH
Java Reference epoch: 1970-01-01T00:00:00 Universal Time Coordinate.
|
static AbsoluteDate |
JULIAN_EPOCH
Reference epoch for julian dates: -4712-01-01T12:00:00 Terrestrial Time.
|
static AbsoluteDate |
MODIFIED_JULIAN_EPOCH
Reference epoch for modified julian dates: 1858-11-17T00:00:00 Terrestrial Time.
|
static AbsoluteDate |
PAST_INFINITY
Dummy date at infinity in the past direction.
|
static AbsoluteDate |
QZSS_EPOCH
Reference epoch for QZSS weeks: 1980-01-06T00:00:00 QZSS time.
|
Constructor and Description |
---|
AbsoluteDate()
Create an instance with a default value (
J2000_EPOCH ). |
AbsoluteDate(AbsoluteDate since,
double elapsedDuration)
Build an instance from an elapsed duration since to another instant.
|
AbsoluteDate(AbsoluteDate reference,
double apparentOffset,
TimeScale timeScale)
Build an instance from an apparent clock offset with respect to another
instant in the perspective of a specific
time scale . |
AbsoluteDate(DateComponents date,
TimeComponents time,
TimeScale timeScale)
Build an instance from a location in a
time scale . |
AbsoluteDate(DateComponents date,
TimeScale timeScale)
Build an instance from a location in a
time scale . |
AbsoluteDate(DateTimeComponents location,
TimeScale timeScale)
Build an instance from a location in a
time scale . |
AbsoluteDate(Date location,
TimeScale timeScale)
Build an instance from a location in a
time scale . |
AbsoluteDate(int year,
int month,
int day,
int hour,
int minute,
double second,
TimeScale timeScale)
Build an instance from a location in a
time scale . |
AbsoluteDate(int year,
int month,
int day,
TimeScale timeScale)
Build an instance from a location in a
time scale . |
AbsoluteDate(int year,
Month month,
int day,
int hour,
int minute,
double second,
TimeScale timeScale)
Build an instance from a location in a
time scale . |
AbsoluteDate(int year,
Month month,
int day,
TimeScale timeScale)
Build an instance from a location in a
time scale . |
AbsoluteDate(String location,
TimeScale timeScale)
Build an instance from a location (parsed from a string) in a
time scale . |
Modifier and Type | Method and Description |
---|---|
int |
compareTo(AbsoluteDate date)
Compare the instance with another date.
|
static AbsoluteDate |
createBesselianEpoch(double besselianEpoch)
Build an instance corresponding to a Besselian Epoch (BE).
|
static AbsoluteDate |
createJDDate(int jd,
double secondsSinceNoon,
TimeScale timeScale)
Build an instance corresponding to a Julian Day date.
|
static AbsoluteDate |
createJulianEpoch(double julianEpoch)
Build an instance corresponding to a Julian Epoch (JE).
|
static AbsoluteDate |
createMJDDate(int mjd,
double secondsInDay,
TimeScale timeScale)
Build an instance corresponding to a Modified Julian Day date.
|
double |
durationFrom(AbsoluteDate instant)
Compute the physically elapsed duration between two instants.
|
boolean |
equals(Object date)
Check if the instance represent the same time as another instance.
|
DateTimeComponents |
getComponents(int minutesFromUTC)
Split the instance into date/time components for a local time.
|
DateTimeComponents |
getComponents(TimeScale timeScale)
Split the instance into date/time components.
|
DateTimeComponents |
getComponents(TimeZone timeZone)
Split the instance into date/time components for a time zone.
|
AbsoluteDate |
getDate()
Get the date.
|
int |
hashCode()
Get a hashcode for this date.
|
double |
offsetFrom(AbsoluteDate instant,
TimeScale timeScale)
Compute the apparent clock offset between two instant in the
perspective of a specific
time scale . |
static AbsoluteDate |
parseCCSDSCalendarSegmentedTimeCode(byte preambleField,
byte[] timeField)
Build an instance from a CCSDS Calendar Segmented Time Code (CCS).
|
static AbsoluteDate |
parseCCSDSDaySegmentedTimeCode(byte preambleField,
byte[] timeField,
DateComponents agencyDefinedEpoch)
Build an instance from a CCSDS Day Segmented Time Code (CDS).
|
static AbsoluteDate |
parseCCSDSUnsegmentedTimeCode(byte preambleField1,
byte preambleField2,
byte[] timeField,
AbsoluteDate agencyDefinedEpoch)
Build an instance from a CCSDS Unsegmented Time Code (CUC).
|
AbsoluteDate |
shiftedBy(double dt)
Get a time-shifted date.
|
double |
timeScalesOffset(TimeScale scale1,
TimeScale scale2)
Compute the offset between two time scales at the current instant.
|
Date |
toDate(TimeScale timeScale)
Convert the instance to a Java
Date . |
String |
toString()
Get a String representation of the instant location in UTC time scale.
|
String |
toString(int minutesFromUTC)
Get a String representation of the instant location for a local time.
|
String |
toString(TimeScale timeScale)
Get a String representation of the instant location.
|
String |
toString(TimeZone timeZone)
Get a String representation of the instant location for a time zone.
|
public static final AbsoluteDate JULIAN_EPOCH
Both java.util.Date
and DateComponents
classes
follow the astronomical conventions and consider a year 0 between
years -1 and +1, hence this reference date lies in year -4712 and not
in year -4713 as can be seen in other documents or programs that obey
a different convention (for example the convcal
utility).
public static final AbsoluteDate MODIFIED_JULIAN_EPOCH
public static final AbsoluteDate FIFTIES_EPOCH
public static final AbsoluteDate CCSDS_EPOCH
public static final AbsoluteDate GALILEO_EPOCH
public static final AbsoluteDate GPS_EPOCH
public static final AbsoluteDate QZSS_EPOCH
public static final AbsoluteDate BEIDOU_EPOCH
public static final AbsoluteDate GLONASS_EPOCH
By convention, TGLONASS = UTC + 3 hours.
public static final AbsoluteDate J2000_EPOCH
public static final AbsoluteDate JAVA_EPOCH
Between 1968-02-01 and 1972-01-01, UTC-TAI = 4.213 170 0s + (MJD - 39 126) x 0.002 592s. As on 1970-01-01 MJD = 40587, UTC-TAI = 8.000082s
public static final AbsoluteDate PAST_INFINITY
public static final AbsoluteDate FUTURE_INFINITY
public AbsoluteDate()
J2000_EPOCH
).public AbsoluteDate(String location, TimeScale timeScale)
time scale
.
The supported formats for location are mainly the ones defined in ISO-8601 standard,
the exact subset is explained in DateTimeComponents.parseDateTime(String)
,
DateComponents.parseDate(String)
and TimeComponents.parseTime(String)
.
As CCSDS ASCII calendar segmented time code is a trimmed down version of ISO-8601, it is also supported by this constructor.
location
- location in the time scale, must be in a supported formattimeScale
- time scaleIllegalArgumentException
- if location string is not in a supported formatpublic AbsoluteDate(DateTimeComponents location, TimeScale timeScale)
time scale
.location
- location in the time scaletimeScale
- time scalepublic AbsoluteDate(DateComponents date, TimeComponents time, TimeScale timeScale)
time scale
.date
- date location in the time scaletime
- time location in the time scaletimeScale
- time scalepublic AbsoluteDate(int year, int month, int day, int hour, int minute, double second, TimeScale timeScale) throws IllegalArgumentException
time scale
.year
- year number (may be 0 or negative for BC years)month
- month number from 1 to 12day
- day number from 1 to 31hour
- hour number from 0 to 23minute
- minute number from 0 to 59second
- second number from 0.0 to 60.0 (excluded)timeScale
- time scaleIllegalArgumentException
- if inconsistent arguments
are given (parameters out of range)public AbsoluteDate(int year, Month month, int day, int hour, int minute, double second, TimeScale timeScale) throws IllegalArgumentException
time scale
.year
- year number (may be 0 or negative for BC years)month
- month enumerateday
- day number from 1 to 31hour
- hour number from 0 to 23minute
- minute number from 0 to 59second
- second number from 0.0 to 60.0 (excluded)timeScale
- time scaleIllegalArgumentException
- if inconsistent arguments
are given (parameters out of range)public AbsoluteDate(DateComponents date, TimeScale timeScale) throws IllegalArgumentException
time scale
.
The hour is set to 00:00:00.000.
date
- date location in the time scaletimeScale
- time scaleIllegalArgumentException
- if inconsistent arguments
are given (parameters out of range)public AbsoluteDate(int year, int month, int day, TimeScale timeScale) throws IllegalArgumentException
time scale
.
The hour is set to 00:00:00.000.
year
- year number (may be 0 or negative for BC years)month
- month number from 1 to 12day
- day number from 1 to 31timeScale
- time scaleIllegalArgumentException
- if inconsistent arguments
are given (parameters out of range)public AbsoluteDate(int year, Month month, int day, TimeScale timeScale) throws IllegalArgumentException
time scale
.
The hour is set to 00:00:00.000.
year
- year number (may be 0 or negative for BC years)month
- month enumerateday
- day number from 1 to 31timeScale
- time scaleIllegalArgumentException
- if inconsistent arguments
are given (parameters out of range)public AbsoluteDate(Date location, TimeScale timeScale)
time scale
.location
- location in the time scaletimeScale
- time scalepublic AbsoluteDate(AbsoluteDate since, double elapsedDuration)
It is important to note that the elapsed duration is not
the difference between two readings on a time scale. As an example,
the duration between the two instants leading to the readings
2005-12-31T23:59:59 and 2006-01-01T00:00:00 in the UTC
time scale is not 1 second, but a stop watch would have measured
an elapsed duration of 2 seconds between these two instances because a leap
second was introduced at the end of 2005 in this time scale.
This constructor is the reverse of the durationFrom(AbsoluteDate)
method.
since
- start instant of the measured durationelapsedDuration
- physically elapsed duration from the since
instant, as measured in a regular time scaledurationFrom(AbsoluteDate)
public AbsoluteDate(AbsoluteDate reference, double apparentOffset, TimeScale timeScale)
time scale
.
It is important to note that the apparent clock offset is the
difference between two readings on a time scale and not an elapsed
duration. As an example, the apparent clock offset between the two instants
leading to the readings 2005-12-31T23:59:59 and 2006-01-01T00:00:00 in the
UTC
time scale is 1 second, but the elapsed duration is 2
seconds because a leap second has been introduced at the end of 2005 in this
time scale.
This constructor is the reverse of the offsetFrom(AbsoluteDate,
TimeScale)
method.
reference
- reference instantapparentOffset
- apparent clock offset from the reference instant
(difference between two readings in the specified time scale)timeScale
- time scale with respect to which the offset is definedoffsetFrom(AbsoluteDate, TimeScale)
public static AbsoluteDate parseCCSDSUnsegmentedTimeCode(byte preambleField1, byte preambleField2, byte[] timeField, AbsoluteDate agencyDefinedEpoch)
CCSDS Unsegmented Time Code is defined in the blue book: CCSDS Time Code Format (CCSDS 301.0-B-4) published in November 2010
If the date to be parsed is formatted using version 3 of the standard
(CCSDS 301.0-B-3 published in 2002) or if the extension of the preamble
field introduced in version 4 of the standard is not used, then the
preambleField2
parameter can be set to 0.
preambleField1
- first byte of the field specifying the format, often
not transmitted in data interfaces, as it is constant for a given data interfacepreambleField2
- second byte of the field specifying the format
(added in revision 4 of the CCSDS standard in 2010), often not transmitted in data
interfaces, as it is constant for a given data interface (value ignored if presence
not signaled in preambleField1
)timeField
- byte array containing the time codeagencyDefinedEpoch
- reference epoch, ignored if the preamble field
specifies the CCSDS reference epoch
is used (and hence
may be null in this case)public static AbsoluteDate parseCCSDSDaySegmentedTimeCode(byte preambleField, byte[] timeField, DateComponents agencyDefinedEpoch)
CCSDS Day Segmented Time Code is defined in the blue book: CCSDS Time Code Format (CCSDS 301.0-B-4) published in November 2010
preambleField
- field specifying the format, often not transmitted in
data interfaces, as it is constant for a given data interfacetimeField
- byte array containing the time codeagencyDefinedEpoch
- reference epoch, ignored if the preamble field
specifies the CCSDS reference epoch
is used (and hence
may be null in this case)public static AbsoluteDate parseCCSDSCalendarSegmentedTimeCode(byte preambleField, byte[] timeField)
CCSDS Calendar Segmented Time Code is defined in the blue book: CCSDS Time Code Format (CCSDS 301.0-B-4) published in November 2010
preambleField
- field specifying the format, often not transmitted in
data interfaces, as it is constant for a given data interfacetimeField
- byte array containing the time codepublic static AbsoluteDate createJDDate(int jd, double secondsSinceNoon, TimeScale timeScale)
jd
- Julian daysecondsSinceNoon
- seconds in the Julian day
(BEWARE, Julian days start at noon, so 0.0 is noon)timeScale
- time scale in which the seconds in day are definedpublic static AbsoluteDate createMJDDate(int mjd, double secondsInDay, TimeScale timeScale) throws OrekitIllegalArgumentException
mjd
- modified Julian daysecondsInDay
- seconds in the daytimeScale
- time scale in which the seconds in day are definedOrekitIllegalArgumentException
- if seconds number is out of rangepublic static AbsoluteDate createJulianEpoch(double julianEpoch)
According to Lieske paper: Precession Matrix Based on IAU (1976) System of Astronomical Constants, Astronomy and Astrophysics, vol. 73, no. 3, Mar. 1979, p. 282-284, Julian Epoch is related to Julian Ephemeris Date as:
JE = 2000.0 + (JED - 2451545.0) / 365.25
This method reverts the formula above and computes an AbsoluteDate
from the Julian Epoch.
julianEpoch
- Julian epoch, like 2000.0 for defining the classical reference J2000.0J2000_EPOCH
,
createBesselianEpoch(double)
public static AbsoluteDate createBesselianEpoch(double besselianEpoch)
According to Lieske paper: Precession Matrix Based on IAU (1976) System of Astronomical Constants, Astronomy and Astrophysics, vol. 73, no. 3, Mar. 1979, p. 282-284, Besselian Epoch is related to Julian Ephemeris Date as:
BE = 1900.0 + (JED - 2415020.31352) / 365.242198781
This method reverts the formula above and computes an AbsoluteDate
from the Besselian Epoch.
besselianEpoch
- Besselian epoch, like 1950 for defining the classical reference B1950.0createJulianEpoch(double)
public AbsoluteDate shiftedBy(double dt)
Calling this method is equivalent to call new AbsoluteDate(this, dt)
.
shiftedBy
in interface TimeShiftable<AbsoluteDate>
dt
- time shift in secondsPVCoordinates.shiftedBy(double)
,
Attitude.shiftedBy(double)
,
Orbit.shiftedBy(double)
,
SpacecraftState.shiftedBy(double)
public double durationFrom(AbsoluteDate instant)
The returned duration is the number of seconds physically
elapsed between the two instants, measured in a regular time
scale with respect to surface of the Earth (i.e either the TAI scale
, the TT scale
or the GPS scale
). It is the only method that gives a
duration with a physical meaning.
This method gives the same result (with less computation)
as calling offsetFrom(AbsoluteDate, TimeScale)
with a second argument set to one of the regular scales cited
above.
This method is the reverse of the AbsoluteDate(AbsoluteDate,
double)
constructor.
instant
- instant to subtract from the instanceoffsetFrom(AbsoluteDate, TimeScale)
,
AbsoluteDate(AbsoluteDate, double)
public double offsetFrom(AbsoluteDate instant, TimeScale timeScale)
time scale
.
The offset is the number of seconds counted in the given
time scale between the locations of the two instants, with
all time scale irregularities removed (i.e. considering all
days are exactly 86400 seconds long). This method will give
a result that may not have a physical meaning if the time scale
is irregular. For example since a leap second was introduced at
the end of 2005, the apparent offset between 2005-12-31T23:59:59
and 2006-01-01T00:00:00 is 1 second, but the physical duration
of the corresponding time interval as returned by the durationFrom(AbsoluteDate)
method is 2 seconds.
This method is the reverse of the AbsoluteDate(AbsoluteDate,
double, TimeScale)
constructor.
instant
- instant to subtract from the instancetimeScale
- time scale with respect to which the offset should
be computeddurationFrom(AbsoluteDate)
,
AbsoluteDate(AbsoluteDate, double, TimeScale)
public double timeScalesOffset(TimeScale scale1, TimeScale scale2)
The offset is defined as l₁-l₂
where l₁ is the location of the instant in
the scale1
time scale and l₂ is the
location of the instant in the scale2
time scale.
scale1
- first time scalescale2
- second time scalepublic Date toDate(TimeScale timeScale)
Date
.
Conversion to the Date class induces a loss of precision because the Date class does not provide sub-millisecond information. Java Dates are considered to be locations in some times scales.
timeScale
- time scale to useDate
instance representing the location
of the instant in the time scalepublic DateTimeComponents getComponents(TimeScale timeScale)
timeScale
- time scale to usepublic DateTimeComponents getComponents(int minutesFromUTC)
minutesFromUTC
- offset in minutes from UTC (positive Eastwards UTC,
negative Westward UTC)public DateTimeComponents getComponents(TimeZone timeZone)
timeZone
- time zonepublic int compareTo(AbsoluteDate date)
compareTo
in interface Comparable<AbsoluteDate>
date
- other date to compare the instance topublic AbsoluteDate getDate()
getDate
in interface TimeStamped
public boolean equals(Object date)
public int hashCode()
public String toString()
public String toString(TimeScale timeScale)
timeScale
- time scale to usepublic String toString(int minutesFromUTC)
minutesFromUTC
- offset in minutes from UTC (positive Eastwards UTC,
negative Westward UTC).Copyright © 2002-2019 CS Systèmes d'information. All rights reserved.