Magneto-resistive stationary heads Unlike
helical scan systems such as DAT or
VHS, the head is stationary and the tape moves in linear direction relative to the head. Like analog audio tapes, the heads use half of the tape width in each direction. There are 9 tracks per side: eight tracks for the audio, and one track for auxiliary information. The track pitch is 195 μm. The head assembly has what Philips called "Fixed Azimuth Tape Guidance" (FATG) pins, which work together with the "Azimuth Locking Pins System" (ALPS) in the cassette to guide the tape. but in portable recorders and players, the head assemblies had heads for the tracks on both sides, which saved space in the mechanism, but made the head assembly more complicated: • Pivoting head mechanisms in stationary recorders such as the DCC-900 used a head assembly that had 9 (MR) playback heads and 9 (coil) recording heads for DCC, plus two (MR) heads for playing analog compact cassettes. The head assembly was mounted on a pivoting mechanism that rotated the head assembly by 180 degrees when it switched from one side of the tape to the other. • Playback-only portable players such as the DCC-130 and DCC-134 used head assemblies with 18 MR heads, nine for each side of the tape. When playing analog cassettes, two of the DCC MR heads were used to pick up the analog audio. • Portable recorders such as the DCC-170 and DCC-175 used head assemblies with 18 MR heads for DCC playback, 18 coil heads for DCC recording, and 4 MR heads for analog playback (a total of 40 heads in one head assembly). Magneto-resistive heads do not use iron so they do not build up residual magnetism. They never need to be demagnetized, and if a magnetic field from e.g. a
cassette demagnetizer is applied to MR heads, it
induces so much current into the heads that they are damaged or destroyed. Also, it is recommended never to use a
cleaning cassette as DCC heads are fragile and this operation could ruin them permanently.
Tape specifications and PASC audio compression DCC tape is the same width as in analog compact cassettes, and operates at the same speed: per second. The tape that was used in production cassettes was chromium dioxide- or cobalt-doped
ferric oxide, 3–4 μm thick in a total tape thickness of 12 μm, identical to the tape that was widely in use for video tapes. Nine heads are used to read/write half the width of the tape; the other half of the width are used for the B-side. Eight of these tracks contain audio data, the ninth track is used for auxiliary information such as song titles and track markers, as well as markers to make the player switch from side A to side B (with or without winding towards the end of the tape first) and end-of-tape markers. The (theoretical) maximum capacity of a DCC tape is 120 minutes, compared to 3 hours for DAT; however, no 120-minute tapes were ever produced. Also, because of the time needed for the mechanism to switch direction, there is always a short interruption in the audio between the two sides of the tape. DCC recorders could record from digital sources that used the
S/PDIF standard, at sample rates of 32 kHz, 44.1 kHz or 48 kHz, or they could record from analog sources at 44.1 kHz. Because of the low tape speed, the achievable
bit rate of DCC is limited. To compensate, DCC uses Precision Adaptive Sub-band Coding (PASC) for
audio data compression. PASC was later integrated into the ISO/IEC 11172-3 standard as
MPEG-1 Audio Layer I (MP1). Though MP1 allows various bit rates, PASC is fixed at 384
kilobits per second. The bandwidth of a CD recording of approximately 1.4
megabits per second is reduced to 384
kilobits per second, a compression ratio of around 3.68:1. The difference in quality between PASC and the 5:1 compression used by early versions of
ATRAC in the original MiniDisc is largely a subjective matter. After adding system information (such as emphasis settings, SCMS information, and time code) as well as adding
Reed-Solomon error correction bits to the 384 kbit/s data stream, followed by
8b/10b encoding, the resulting bit rate on the eight main data tracks tape ends up being twice the rate of the original PASC data: 768 kbit/s, which is recorded onto the eight main data tracks at 96 kbit/s per track in an interleaved pattern. According to the Philips webpage, DCCs are similar to analog compact cassettes, except that there are no "bulges" where the tape-access holes are located. DCC cassettes are flat and there are no access holes for the hubs on the top side (they are not required because auto-reverse is a standard feature on all DCC decks), so this side can be used for a larger label than can be used on an analog compact cassette. A spring-loaded metal shutter similar to the shutters on 3.5 inch
floppy disks and MiniDiscs covers the tape access holes and locks the hubs while the cassette is not in use. Cassettes provide several extra holes and indentations so that DCC recorders can tell a DCC apart from an analog compact cassette, and so they can tell what the length of a DCC tape is. Also, there is a sliding write-protect tab on the DCC to enable and disable recording. Unlike the break-away notches on analog compact cassettes and VHS tapes, this tab makes it easier to make a tape recordable again, and unlike on analog compact cassettes, the marker protects the entire tape rather than just one side. The cases that DCCs came in generally did not have the characteristic folding mechanism used for analog compact cassettes. Instead, DCC cases tended to be simple plastic boxes that were open on one of the short sides. The front side had a rectangular opening that exposed almost the entire cassette, so that any label on the cassette would be visible even when the cassette was in its case. This allowed the user to slide the cassette into and out of the case with one hand (which was seen as a major advantage for mobile use shows that in the recorder, the cable is connected to the
I²S bus that carries the PASC bitstream, and it is also connected to a dedicated serial port of the microcontroller, to allow the PC to control the mechanism and to read and write auxiliary information such as track markers and track titles. The parallel port connector of the cable contains a custom chip created especially for this purpose by Philips Key Modules, as well as a standard
RAM chip. Philips made no detailed technical information available to the public about the custom chip and therefore it is impossible for people who own a DCC-175 but no PC-link cable to make their own version of the PC-link cable. The PC-link cable package included software consisting of: • DCC Backup for Windows, a backup program • DCC Studio, a sound recorder and editor for Windows • A DCC tape database program that works together with DCC Studio Philips also provided a DOS backup application via their
BBS, and later on they provided an upgrade to the DCC Studio software to fix some bugs and provide better compatibility with
Windows 95 which had come out just before the release of the DCC-175. The software also works with Windows 98, Windows 98SE and Windows ME, but not with any later versions of Windows. The backup programs for DOS as well as Windows does not support long file names which had been introduced by Windows 95 just a few months before the release. Also, because the tape runs at its usual speed and data rate, it takes 90 minutes to record approximately 250
megabytes of uncompressed data. Other backup media common in those days were faster, had more capacity, and supported long file names, so the DCC backup programs were relatively unhelpful for users. The DCC Studio application, however, was a useful application that made it possible to copy audio from tape to hard disk and vice versa, regardless of the SCMS status of the tape. This made it possible to circumvent SCMS with DCC Studio. The program also allowed users to manipulate the PASC audio files that were recorded to hard disk in various ways: they could change equalization settings, cut/copy and paste track fragments, and place and move audio markers and name those audio markers from the PC keyboard. It was possible to record a mix tape by selecting the desired tracks from a list, and moving the tracks around in a playlist. Then the user could click on the record button to copy the entire playlist back to DCC tape, while simultaneously recording markers (such as reverse and end-of-tape) and track titles. It was not necessary to record the track titles and tape markers separately (as you would do with a stationary recorder), and thanks to the use of a PC keyboard, it was possible to use characters in song titles that were not available when using a stationary machine's remote control. The DCC Studio program used the recorder as playback and recording device, avoiding the need for a separate
sound card, an uncommon accessory at the time. Working with the PASC data directly without the need to compress and decompress, also saved a lot of hard disk space, and most computers at the time would have had a hard time compressing and decompressing PASC data in real time anyway. However, many users complained that they would have liked to have the possibility of using uncompressed
WAV audio files with the DCC Studio program, and Philips responded by mailing a
floppy disk to registered users, containing programs to convert a WAV file to PASC and vice versa. Unfortunately this software was extremely slow (it takes several hours to compress a few minutes of PCM music in a WAV file to PASC) but it was soon discovered that the PASC files are simply MPEG-1 Audio Layer I files that use an under-documented padding feature of the MPEG standard to make all frames the same length, so then it became easy to use other MPEG decoding software to convert PASC to
PCM and vice versa. == Derivatives ==