We hope that some of our readers are currently at this year’s Chaos Communication Congress (schedule can be found here and live streams here), as many interesting talks are happening. One of them addressed hacking the memory controllers embedded in all memory cards that you may have. As memory storage density increases, it’s more likely that some sectors inside the embedded flash are defective. Therefore, all manufacturers add a small microcontroller to their cards (along with extra memory) to invisibly ‘replace’ the defective sectors to the operating system.
[Bunnie] and [xobs] went around buying many different microSD cards in order to find a hackable one. In their talk at 30C3 (slides here), they reported their findings on a particular microcontroller brand, Appotech, and its AX211/AX215. By reverse engineering the firmware code they found online, they discovered a simple “knock” sequence transmitted over manufacturer-reserved commands that dropped the controller into a firmware loading mode.
From there, they were able to reverse engineer most of the 8051 microcontroller function-specific registers, allowing them to develop novel applications for it. Some of the initial work was done using a FPGA/i.MX6-based platform that the team developed named Novena, which we hope may be available for purchase some day. It was, among others, used to simulate the FLASH memory chip that the team had previously removed. A video of the talk is embedded below.
[Bunnie] and [xobs] went around buying many different microSD cards in order to find a hackable one. In their talk at 30C3 (slides here), they reported their findings on a particular microcontroller brand, Appotech, and its AX211/AX215. By reverse engineering the firmware code they found online, they discovered a simple “knock” sequence transmitted over manufacturer-reserved commands that dropped the controller into a firmware loading mode.
From there, they were able to reverse engineer most of the 8051 microcontroller function-specific registers, allowing them to develop novel applications for it. Some of the initial work was done using a FPGA/i.MX6-based platform that the team developed named Novena, which we hope may be available for purchase some day. It was, among others, used to simulate the FLASH memory chip that the team had previously removed. A video of the talk is embedded below.
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