I'm getting radar data as "tracks" and the track data indicates the number of UTC seconds since the last midnight, apparently. This is not the number of seconds since the 1st of jan 1970.

Now I want to convert that to date time, knowing that the clock on the computer could be slightly out of sync with the clock on the radar. I'll assume the radar's seconds are the reference, not the computer's. I want to convert these seconds to a full date time. Things seem to be a little tricky around midnight.

Any suggestions? I've got some ideas, but I don't want to miss anything.

I'm working with C++ Qt.

//  Function to extend truncated time, given the wall time and period, all
//  in units of seconds.
//  Example: Suppose the truncated period was one hour, and you were
//  given a truncated time of 25 minutes after the hour. Then:
//  o Actual time of 07:40:00 results in 07:25:00 (07:40 + -15)
//  o Actual time of 07:10:00 results in 07:25:00 (07:10 + +15)
//  o Actual time of 07:56:00 results in 08:25:00 (07:56 + +29)

double extendTruncatedTime(double trunc, double wall, int period) {
   return wall + remainder(trunc - wall, period);

#define extendTruncatedTime24(t) extendTruncatedTime(t, time(0), 24 * 60 * 60)

Some commentary:

  • The units of wall are seconds, but its base can be arbitrary. In Unix, it typically starts at 1970.

  • Leap seconds are not relevant here.

  • You need #include <math.h> for remainder().

  • The period in extendTruncatedTime() is almost always twenty-four hours, 24 * 60 * 60, as per the OP's request. That is, given the time of day, it extends it by adding the year, month, and day of month, based on the 'wall' time.

  • The only exception I know to the previous statement is, since you mention radar, is in the Asterix CAT 1 data item I001/141, where the period is 512 seconds, and for which extendTruncatedTime() as given doesn't quite work.

  • And there is another important case which extendTruncatedTime() doesn't cover. Suppose you are given a truncated time consisting of the day of month, hour, and minute. How can you fill in the year and the month?

The following code snippet adds the year and month to a time derived from a DDHHMM format:

time_t extendTruncatedTimeDDHHMM(time_t trunc, time_t wall) {
   struct tm retval = *gmtime_r(&trunc, &retval);
   struct tm now    = *gmtime_r(&wall,  &now);
   retval.tm_year = now.tm_year;
   retval.tm_mon  = now.tm_mon;
   retval.tm_mon += now.tm_mday - retval.tm_mday >  15; // 15 = half-month
   retval.tm_mon -= now.tm_mday - retval.tm_mday < -15;
   return timegm(&retval);

As written, this doesn't handle erroneous inputs. For example, if today is July 4th, then the non-nonsensical 310000 will be quietly converted to July 1st. (This may be a feature, not a bug.)


If you can link against another lib, i'd suggest to use boost::date_time.

It seems you want to take current date in seconds from midnight (epoch) then add the radar time to it, then convert the sum back to a date time, and transform it into a string.

Using boost will help you in:

  • getting the right local time
  • calculating the date back
  • incorporating the drift into the calculation
  • taking leap seconds into account

since you'll have concept like time intervals and durations at your disposal. You can use something like (from the boost examples):

ptime t4(date(2002,May,31), hours(20)); //4 hours b/f midnight NY time
ptime t5 = us_eastern::local_to_utc(t4);
std::cout << to_simple_string(t4) << " in New York is " 
          << to_simple_string(t5) << " UTC time "
          << std::endl;

If you want to calculate the drift by hand you can do time math easily similar to constructs like this:

 ptime t2 = t1 - hours(5)- minutes(4)- seconds(2)- millisec(1);
  • 1
    Yes, but how do you account for the fact that, for a few minutes each day, the computer running the code may have a different date than the radar. – Gabe Oct 12 '12 at 12:51
  • 1
    If the clock has a drift, it'll have to be synchronized with a protocol, e.g. NTP. Unless one wants to do the sync by hand, which just means measuring the drift in fixed time intervals and calculating the offset of the average drift. If the drift is so large that it advances to the next day, one can incorporate that into the computation and subtract. After all constructing the time is being done on the user side. Imho not very hard once the time arithmetic is correct which would be covered by using boost. – count0 Oct 12 '12 at 12:52

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