MediaWiki API result
This is the HTML representation of the JSON format. HTML is good for debugging, but is unsuitable for application use.
Specify the format parameter to change the output format. To see the non-HTML representation of the JSON format, set format=json.
See the complete documentation, or the API help for more information.
{
"batchcomplete": "",
"continue": {
"gapcontinue": "SMT100",
"continue": "gapcontinue||"
},
"warnings": {
"main": {
"*": "Subscribe to the mediawiki-api-announce mailing list at <https://lists.wikimedia.org/postorius/lists/mediawiki-api-announce.lists.wikimedia.org/> for notice of API deprecations and breaking changes."
},
"revisions": {
"*": "Because \"rvslots\" was not specified, a legacy format has been used for the output. This format is deprecated, and in the future the new format will always be used."
}
},
"query": {
"pages": {
"29": {
"pageid": 29,
"ns": 0,
"title": "SDR2",
"revisions": [
{
"contentformat": "text/x-wiki",
"contentmodel": "wikitext",
"*": "=== Is the free Xilinx ISE webpack provided by Xilinx usable with this SDR-2 kit? ===\n\nNo, it isn't.\n\nThe Xilinx webpack supports only small FPGA devices.\n\nIt is required to use the Xilinx ISE Foundation software to access the SDR-2 Virtex-4 FX60 FPGA devices.\n\n\n=== What software for SDR-2 kit is available under MATLAB? ===\n\nThere are full support from: SMT6040, SMT6041, PARS and even MATLAB/Simulink Real Time Workshop, Simulink HDL-coder and Xilinx System Generator that are fully compatible with the 3L Diamond tools.\n\nOther design approaches are available like \"C-to-FPGA\" compilers like Impulse-C."
}
]
},
"30": {
"pageid": 30,
"ns": 0,
"title": "SLB Mezzanine",
"revisions": [
{
"contentformat": "text/x-wiki",
"contentmodel": "wikitext",
"*": "Every DSP or FPGA application has varying input and output requirements. These can\nbe simple USB interfaces, CameraLink, or high-speed analog I/O. Utilising a standard\nbase module, a flexible system can be tailored by attaching a wide variety of daughter\nmodules. For this reason, the SLB mezzanine concept was introduced.\n\nThis concept consists of a carrier board (often a DSP or FPGA TIM module) which\nincludes a high density connector. This connector accepts a daughter module (or\nmezzanine) which is mounted above the carrier (or in some case can be mounted\nseparately and joined using a flexible cable).\n\nThe SLB connector is of a differential construction (based on a Samtec QSH/QTH-DP\nseries 0.5mm pitch connectors) and characterised for high-speed data of over 1Gb/s per\npin pair.\n\nThe connector is split into three sections, 2 for high-speed differential (LVDS) data\ntransfer, and one for control. A separate connector provides power to the mezzanine\nboard.\n\nBelow are listed the features of the SLB:\n* Low Voltage Differential Signalling (LVDS), supported by Xilinx FPGAs,\n* One control signal port,\n* Two differential data ports,\n* A set of power supplies: +3.3, +5, +12 and \u201312 Volts.\n* Two-extra mounting holes to hold Main/Base and Daughter modules together.\n\nFull information about the SLB Standard can be found in the [http://tinyurl.com/slb-specification SLB (Sundance Local Bus) Specification (PDF)]\n\nListed below is a table of the I/O voltages for various SLB modules.\nThis table will be updated as and when the information becomes available.\n\n<table border=\"1\" width=\"300\">\n<tr>\n <th>SLB Module</th>\n <th>I/O Level</th>\n</tr>\n<tr>\n <td>SMT350</td>\n <td>3.3V</td>\n</tr>\n<tr>\n <td>SMT381</td>\n <td>2.5V</td>\n</tr>\n<tr>\n <td>SMT384</td>\n <td>3.3V</td>\n</tr>\n<tr>\n <td>SMT390</td>\n <td>3.3V</td>\n</tr>\n<tr>\n <td>SMT391</td>\n <td>2.5V</td>\n</tr>\n<tr>\n <td>SMT399-160</td>\n <td>3.3V</td>\n</tr>\n<tr>\n <td>SMT903</td>\n <td>3.3V</td>\n</tr>\n<tr>\n <td>SMT909</td>\n <td>2.5V</td>\n</tr>\n<tr>\n <td>SMT911</td>\n <td>3.3V</td>\n</tr>\n<tr>\n <td>SMT916</td>\n <td>2.5V</td>\n</tr>\n<tr>\n <td>SMT922</td>\n <td>2.5V</td>\n</tr>\n<tr>\n <td>SMT939</td>\n <td>2.5V</td>\n</tr>\n<tr>\n <td>SMT941</td>\n <td>2.5V</td>\n</tr>\n<tr>\n <td>SMT942</td>\n <td>2.5V</td>\n</tr>\n<tr>\n <td>SMT943</td>\n <td>2.5V</td>\n</tr>\n<tr>\n <td>SMT945</td>\n <td>2.5V Drive or 2.5V/3.3V Receive</td>\n</tr>\n<tr>\n <td>SMT946</td>\n <td>2.5V</td>\n</tr>\n<tr>\n <td>SMT949</td>\n <td>2.5V</td>\n</tr>\n<tr>\n <td>SMT950</td>\n <td>3.3V</td>\n</tr>\n<tr>\n <td>SMT959</td>\n <td>2.5V</td>\n</tr>\n</table>"
}
]
}
}
}
}