π Primarily, the .BIT entry specification is eligible for storing encrypted data resources generated and bundled by FinalCrypt, a suite utilized to decrypt and encrypt personal file records and content. In common, the .BIT element includes a file itself, particularly, a .WMV video or .JPG image, that has been previously encrypted and packaged for security targets. .BIT files are typically initiated by FinalCrypt toolkit only and can only be extracted and uncovered by FinalCrypt with the interaction of a specific key applied to encrypt the requested .BIT sample. Internal data within a .BIT element cannot be obtained and extracted without the compound key file, so it is crucially important and vital to keep it in a well-protected and safe location to be able to gain access to it at any moment of time. Despite the .BIT sources being stored in encrypted representation, they still can be recognized and read by the initial, starting 70 bytes of the outcome .BIT file item.
π This accurate .BIT entry definition is made up and opened by BitGen, a suite utilized for generating and constructing bitstreams required by Xilinx FPGAs (the abbreviation stands for field-programmable gate arrays term). The following .BIT document category is stored in a binary shape and includes the configuration data for the relevant circuit. Besides, the .BIT specification is exploited for uploading the configuration data to the FPGA gadget, which can be afterwards completed with the assistance of the iMPACT GUI embedded into the Xilinx software suite. .BIT item construction is generated in a sequence of file objects applied for designing and configuring an FPGA. For instance, a Verliog (.V-formatted) HDL design document branch can be applied to define an .NGC netlist file composition, which is later converted into an .NGD layout, and, at last, is transformed into the bitstream .BIT schema, finally. The BitGen program package is integrated into the Xilinx ISE software bundle.
π A .BIT structure definition may also concern a typical .MP3 audio file with the .BIT format tree, which was utilized formerly, in the early 1990s before being finally superseded and inherited with the .MP3 extension area in 1995. Ordinarily, the .BIT schema is saved in an encoded and packaged MPEG layout that utilizes βLayer 3β audio compression (MP3) codec to reduce the resulting file size without losing much degree of quality. Besides, the .BIT algorithm is pretty frequently used to open and save various songs, but may also handle and process other subdivisions of audio recordings, such as narrations or interviews. The .MP3 technology, a successor of the .BIT mechanic, was initially introduced to the public audience in 1993 by the Moving Picture Experts Group (MPEG) non-profit organization and the .BIT marker tag was initially assigned to the .MP3 audio compositions and sequences. Soon the .MP3 approach became the essential principle for storing and playing back audio compositions, and .BIT layout became absolutely obsolete.
How to open an .BIT file?
π In case the target .BIT file sample includes encrypted data content, most often, it is flawlessly uncovered and opened up by FinalCrypt distributive, mainly target for data encoding and packaging. Otherwise, if the source .BIT entry serves for generating Xilinx FPGA bitstreams, it is perfectly compatible with Xilinx ISE Design Suite, accustomed for uploading and transferring appropriate file content to the FPGA device. In the final preconditions, the .BIT logic may substitute .MP3 format technique, and is commonly played back and reproduced by any general audio players, such as Microsoft Windows Media Player, VLC, Apple iTunes, Elmedia Player, Clementine and other affordable products, remaining in a range of accessibility of your networking conditions. In the latter circumstances, the .BIT format entitlement serves as a predecessor of more contemporary .MP3 entry layout, and was especially popular and broadly spread in the early 1990s. Since 1995 the .MP3 technical algorithm has finally substituted the .BIT logic.