read.adp.rdi: Read a Teledyne/RDI ADP File

1. Early PD0 file formats stored the year of sampling with a different base year than that used in modern files. To accommodate this, read.adp.rdi examines the inferred year, and if it is greater than 2050, then 100 years are subtracted from the time. This offset was inferred by tests with sample files, but not from RDI documentation, so it is somewhat risky. If the authors can find RDI documentation that indicates the condition in which this century offset is required, then a change will be made to the code. Even if not, the method should not cause problems for a long time.

The names of items in the data slot are below. Not all items are present for ll file varieties; use e.g. names(d[["data"]]) to determine the names used in an object named d. In this list, items are either a vector (with one sample per time of measurement), a matrix with first index for time and second for bin number, or an array with first index for time, second for bin number, and third for beam number. Items are of vector type, unless otherwise indicated.

For RDI files only, and only in the case where by is not specified, an attempt is made to avoid running out of memory by skipping some profiles in large input files. This only applies if from and to are both integers; if they are times, none of the rest of this section applies.

A key issue is that RDI files store velocities in 2-byte values, which is not a format that R supports. These velocities become 8-byte (numeric) values in R. Thus, the R object created by read.adp.rdi will require more memory than that of the data file. A scale factor can be estimated by ignoring vector quantities (e.g. time, which has just one value per profile) and concentrating on matrix properties such as velocity, backscatter, and correlation. These three elements have equal dimensions. Thus, each 4-byte slide in the data file (2 bytes + 1 byte + 1 byte) corresponds to 10 bytes in the object (8 bytes + 1 byte + 1 byte). Rounding up the resultant 10/4 to 3 for safety, we conclude that any limit on the size of the R object corresponds to a 3X smaller limit on file size.

Various things can limit the size of objects in R, but a strong upper limit is set by the space the operating system provides to R. The least-performant machines in typical use appear to be Microsoft-Windows systems, which limit R objects to about 2e6 bytes (see ?Memory-limits). Since R routinely duplicates objects for certain tasks (e.g. for call-by-value in function evaluation), read.adp.rdi uses a safety factor in its calculation of when to auto-decimate a file. This factor is set to 3, based partly on the developers' experience with datasets in their possession. Multiplied by the previously stated safety factor of 3, this suggests that the 2 GB limit on R objects corresponds to approximately a 222 MB limit on file size. In the present version of read.adp.rdi, this value is lowered to 200 MB for simplicity. Larger files are considered to be "big", and are decimated unless the user supplies a value for the by argument.

The decimation procedure has two cases.

1. If from=1 and to=0 (or if neither from or to is given), then the intention is to process the full span of the data. If the input file is under 200 MB, then by defaults to 1, so that all profiles are read. For larger files, by is set to the ceiling() of the ratio of input file size to 200 MB.

2. If from exceeds 1, and/or to is nonzero, then the intention is to process only an interior subset of the file. In this case, by is calculated as the ceiling() of the ratio of bbp*(1+to-from) to 200 MB, where bbp is the number of file bytes per profile. Of course, by is set to 1, if this ratio is less than 1.

If the result of these calculations is that by exceeds 1, then messages are printed to alert the user that the file will be decimated, and also monitor is set to TRUE, so that a textual progress bar is shown (if the session is interactive).

An important part of the work of this function is to recognize what will be called "data chunks" by two-byte ID sequences. This function is developed in a practical way, with emphasis being focussed on data files in the possession of the developers. Since Teledyne-RDI tends to introduce new ID codes with new instruments, that means that read.adp.rdi may not work on recently-developed instruments.

The following two-byte ID codes are recognized by read.adp.rdi at this time (with bytes listed in natural order, LSB byte before MSB). Items preceded by an asterisk are recognized, but not handled, and so produce a warning.

Lacking a comprehensive Teledyne-RDI listing of ID codes, the authors have cobbled together a listing from documents to which they have access, as follows.

• Table 33 of reference 3 lists codes as follows:

  Standard ID	Standard plus 1D	DESCRIPTION
  MSB LSB	MSB LSB
  --- ---	--- ---
  7F 7F	7F 7F	Header
  00 00	00 01	Fixed Leader
  00 80	00 81	Variable Leader
  01 00	01 01	Velocity Profile Data
  02 00	02 01	Correlation Profile Data
  03 00	03 01	Echo Intensity Profile Data
  04 00	04 01	Percent Good Profile Data
  05 00	05 01	Status Profile Data
  06 00	06 01	Bottom Track Data
  20 00	20 00	Navigation
  30 00	30 00	Binary Fixed Attitude
  30 40-F0	30 40-F0	Binary Variable Attitude

• Table 6 on p90 of reference 4 lists "Fixed Leader Navigation" ID codes (none of which are handled by read.adp.rdi yet) as follows (the format is reproduced literally; note that e.g. 0x2100 is 0x00,0x21 in the oce notation):

  ID	Description
  0x2100	$xxDBT
  0x2101	$xxGGA
  0x2102	$xxVTG
  0x2103	$xxGSA
  0x2104	$xxHDT, $xxHGD or $PRDID

  and following pages in that manual reveal the following meanings

  Symbol	Meaning
  DBT	depth below transducer
  GGA	global positioning system
  VTA	track made good and ground speed
  GSA	GPS DOP and active satellites
  HDT	heading, true
  HDG	heading, deviation, and variation
  PRDID	heading, pitch and roll

Files can sometimes be corrupted, and read.adp.rdi has ways to handle two types of error that have been noticed in files supplied by users.

1. There are two bytes within each ensemble that indicate the number of bytes to check within that ensemble, to get the checksum. Sometimes, those two bytes can be erroneous, so that the wrong number of bytes are checked, leading to a failed checksum. As a preventative measure, read.adp.rdi checks the stated ensemble length, whenever it detects a failed checksum. If that length agrees with the length of the most recent ensemble that had a good checksum, then the ensemble is declared as faulty and is ignored. However, if the length differs from that of the most recent accepted ensemble, then read.adp.rdi goes back to just after the start of the ensemble, and searches forward for the next two-byte pair, namely 0x7f 0x7f, that designates the start of an ensemble. Distinct notifications are given about these two cases, and they give the byte numbers in the original file, as a way to help analysts who want to look at the data stream with other tools.

2. At the end of an ensemble, the next two characters ought to be 0x7f 0x7f, and if they are not, then the next ensemble is faulty. If this error occurs, read.adp.rdi attempts to recover by searching forward to the next instance of this two-byte pair, discarding any information that is present in the mangled ensemble.

In each of these cases, warnings are printed about ensembles that seem problematic. Advanced users who want to diagnose the problem further might find it helpful to examine the original data file using other tools. To this end, read.adp.rdi inserts an element named ensembleInFile into the metadata slot. This gives the starting byte number of each inferred ensemble within the original data file. For example, if d is an object read with read.adp.rdi, then using

plot(d[["time"]][-1], diff(d[["ensembleInFile"]]))

can be a good way to narrow in on problems.