There were some cassette copying programs for 8-bit Atari, that boasted saving the games in a way that would load it at up to 1800baud - versus the standard 600baud, which was a significant improvement, and without requiring hardware modifications of the cassette recorder.
How did they work? And why wasn't that the standard used everywhere?
(IIRC, the program "Warp Copy" was an example of this.)
If one doesn't need particularly high data rates, it's possible to implement data-to-audio and audio-to-data routines in a very small amount of code. To store a "1", generate 250us of high followed by 250us (e.g.) of low; to store a "0", store 500us of high followed by 500us of low. Note that some tape-drives' electronics, which are designed for analog signals, will try to adjust the signal try receive so that it's high about half the time and low about half the time, and the signal may get badly distorted (and thus become illegible) if the high and low times aren't close to being balanced, which is why tape formats seem to waste half the storage capacity writing each bit twice.
If one is willing to use more complicated code for recording and playback, it's possible to use a mixture of different pulse lengths, encoded in such a fashion that the high and low times remain balanced. Such approaches can allow more than twice as much information to be stored as the simple straightforward technique, but require more code to read or write data. For a computer to include built-in support would have required that manufacturers devote hundreds of bytes of ROM to that purpose that could otherwise be used for other things.
For programs shipped on pre-recorded tapes, however, the size of the record/playback routines is not an issue. The data can be written on the tape using specialized equipment, making the size of the record routines irrelevant [if the encoding is one that couldn't be written by a standard computer, that would actually be a bonus]. The size of playback code is also not much of an issue. Even if playback code would take 1024 bytes, it could be used to load all but 1024 bytes of RAM; if it would be necessary to load even more than that, the last little bit could be loaded using a slower but smaller routine (or perhaps the built-in one).
Actually, in that case, no fancy algorithm changes were used - the tape recorder was literally "overclocked" - frequency of interrupts handling communication with the tape recorder changed.
I found a program that allowed to override speed on the standard C: handler. It allows operation at up to 1400 baud, but as the author writes, the ability to use higher speed is "an individual property of each tape recorder and requires high-quality tapes."
Let me translate the segment of the article that addresses how the program actually works.
For the curious: After being loaded, "Selector" searches hatabs for the address of the C: handler, and basing on it, it creates its own, with modified "OPEN" and CLOSE" procedures. [note, read/write procedures are umodified! --SF.] New table address is attached to the standard handler, so it doesn't ocupy extra space. The speedup is based on modification of the serial bus interrupt vserini and corresponding setting of the POKEY work frequency registers for duration of the transmission. The interrupt change occurs only on opening the C: device and is restored after its closing in order to enable normal use of a disk drive. The control keys are passed from the keyboard interrupt. The program is immune to warm start of the computer. Good luck in turbo'ing!
With Atari, some or combination of the following practices were used:
All these three practices reduced time available to process data (the IRG is present to allow CPU to process the data just read), so some loaders were forced to completely disable DMA (blank screen) or use a display list with minimum CPU overhead (one or two lines of GR.1 or GR.2 to display program name).
