HRDI Data Quality

The following information applies to HRDI level 3a data, version number 7
thru 10.

  Mesospheric zonal and meridional winds:

 
    Altitude Range	The daytime altitude range differs according to modes
			run and time period - there are three main periods:
			1) before UARS day 201 (29-March-1992) HRDI provided
			mesospheric data from two different modes, one of which
			gave results from 80 to 105 km (strato-meso mode), while
			the other covered from 65 to 105 km. These two modes
			were generally alternated on a daily basis during this
			period with our stratospheric mode, so that (for
			example) we might, during a three day period, have
			80-105km coverage, no mesospheric coverage,
			then 65-105 km coverage.
			2) 65 to 105 km between UARS day 201 and UARS day 620
			(22-May-1993),
			3) 50 to 115 km after UARS day 620. Please note that
			some data are available above these altitude ranges,
			at lower quality.

			Nighttime winds are only available at the peak of the
			O2 Atmospheric (0,0) band, which is approximately 94 km
			but varies (and is always reported as 96 km in our
			data).

			In the HRDI level 3a products, if there is only a single
			altitude reported, the data are nighttime winds results.

    Estimated Precision	For these data, precision information is available in
			the 'data quality' field of the file, which holds the
			standard deviations of the measurements. These values
			depend on viewing conditions - at 95 km with low solar
			zenith angle, they can be less than 3 m/s -  under
			'average' conditions (solar zenith angle about 30
			degrees) the standard deviation of the data varies
			(depending on interpolation from level 2 to level 3
			locations) from 6 to 12 m/s at 111 km, from 3 to 7 m/s
			at 95 km, from 8 to 15 m/s at 69 km, from 20 to 40 m/s
			at 50 km.

    Estimated Accuracy	The accuracy of the data set depends on how well we have
			determined the 'zero wind' position for the current
			mode of instrument operation. We have determined the
			'zero wind' position to within 5 m/s for data after
			UARS day 201. Before UARS day 201 (30-March-1992) there
			are some days during which we ran different modes which,
			because of the small size of the data set, cannot be
			validated/calibrated to the same degree as the rest
			of the data set - these are UARS days: 63-79
			(13-November-1991 thru 29-November-1991), 113-120
			(2-January-1992 thru 9-January-1992), 134-149
			(23-January-1992 thru 7-February-1992), 165-173
			(23-February-1992 thru 2-March-1992), 182-189
			(11-March-1992 thru 18-March-1992). The accuracy of
			these data is at or near the 10 m/s level.
 
    Resolution		HRDI collects a 'scan', consisting of a series of
			measurements at different altitudes above the same
			position on the earth, every 30 seconds, on average,
			during the 'day' (when the spacecraft is on the sunlit
			side of the orbit). These data are then linearly
			interpolated onto the UARS standard grids (every 4
			degrees in latitude for L3AT data, or every spacecraft
			'minute' (about 65 seconds) for L3AL data). HRDI makes
			measurements every 2.5km in altitude, which is a
			slightly finer grid than the UARS level 3
			standard (3km from 60km to 120km, 5km elsewhere).

			Before UARS day 394 (9-Oct-1992) HRDI made nighttime
			wind measurements approximately only one day out of
			three; after day 394 nighttime winds were measured
			nearly every day.


  Stratospheric zonal and meridional winds:
 

    Altitude Range	The daytime altitude range is from 15 to 40 km in the
			stratosphere.

    Estimated Precision	For these data, precision information is available in
			the 'data quality' field of the file, which holds the
			standard deviations of the measurements. These values
			depend on viewing conditions.
 
    Estimated Accuracy	Same as in the mesosphere.

    Resolution		Same as in the mesosphere.


  Systematic Effects:	Our level 2a product wind measurements along the
			instrument line of sight are at about our
			required precision, but because of noise added in the
			inversion process, we need to filter out high
			frequencies in our inverted profiles to create our
			level 2b and level 3a products. We accomplish this
			thru the use of sequential estimation, in effect
			taking a weighted average of the current measurement
			and those near it in time and location. As a result,
			some small scal features in the real winds may be
			smoothed out by this process. We continue assembling
			data to verify that our estimating algorithm is
			optimum. No sequential estimation is used in
			determining the nighttime winds.

			The HRDI instrument has had two hardware failures, and
			has also been somewhat effected by the UARS spacecraft
			solar array problem, and by HRDI's exposure to the
			space environment.

			After each of the instrument's hardware failures
			(which occurred on UARS days 201 (30-March-1992) and
			510 (2-February-1993)) we were able to develop
			work-arounds, but as a result we were required to
			change the tuning of our instrument somewhat, which
			means that raw winds measured after each failure were
			shifted somewhat from winds measured beforehand. We
			have been able to calculate and compensate for these
			shifts by comparing with correlative measurements.
			These compensations are part of the version 7 (and
			beyond) data files, but we are still in the process of
			refining our compensation for the day 510 shift.

			When the UARS solar array drive first halted
			(UARS days 266 thru 313, 3-June-1992 thru 20-July-1992)
			our instrument was powered down and got very cold -
			this also caused a change in the way the instrument
			worked, and a shift in the measured winds.
			Compensation for this shift is also included in the
			version 7 (and beyond) data. We believe that the space
			environment has also affected the measured winds.
			We see a long term drift in the measured winds (and in
			the position of on-board calibration lamp lines),
			which we attribute to drying and outgassing of the
			instrument optics (including coatings). Compensation
			for this drift is also included in the version 7
			(and beyond) data files.

			The raw winds measured by the HRDI instrument also
			depend on the temperature of the instrument. We have
			attacked this problem in two ways, first, we have
			tried to calculate the wind drift with temperature,
			and have applied this compensation in the version 7
			(and beyond) data files; we have also developed new
			instrument control software, to narrow the temperature
			range over which the instrument is operated. Both
			of these efforts are still underway.

 
  Caveats:		HRDI started making good wind measurements on UARS day
			day 53 (3-Nov-1991), before that the instrument control
			coefficients were not sufficient to make good wind
			measurements. UARS days 85-90 (5-December-1991 thru
			10-December-1991), 202-226 (31-March-1992 thru
			24-April-1992), 510-519 (2-February-1993 thru
			11-February-1993), and 583-587 (16-April-1993 thru
			20-April-1993) contain invalid winds. No HRDI
			measurements are available for UARS days 266-313
			(3-June-1992 thru 20-July-1992), 694-698 (5-August-1993
			thru 9-August-1993), 737-743 (17-September-1993 thru
			23-September-1993), 753-775 (3-October-1993 thru
			25-October-1993), 1290-1303 (24-March-1995 thru
			6-April-1995), and 1314-? (17-April-1995 thru the
			present) due to problems with the UARS solar array.

			HRDI level 2b data are interpolated to create both L3AT
			and L3AL data files. They are also available on both an
			altitude and pressure grid. We recommend using the
			altitude gridded data for a number of reasons: 1) the
			HRDI instrument makes its measurements on the altitude
			grid, 2) the pressure gridded data are produced using
			NMC pressure/altitude data for the given day, a
			somewhat smoothed product, and 3) the UARS standard
			grid for pressure has a top level of 1.47e-3 mb, or
			about 90 km, while HRDI makes measurements well above
			this level.