The present invention pertains to security systems and more particularly to the sensing of tampering with respect to devices housed within enclosure members secured together by a connector such as a screw or bolt.
The design of data handling devices that may be used for the storage of confidential data will normally require the inclusion of means to detect tampering or the unauthorized disassembly of the device that could be initiated to access the stored confidential data. The smaller the device, the greater the likelihood that it will be lost, mislaid, subject to theft or otherwise be beyond the custody and control of the user and owner of the stored data. In such circumstances, with the device in the possession and control of a party unable to use a password or comply with other requirements to achieve normal access to the stored data, tampering may occur by opening the housing in an attempt to use other extraordinary means to access the data.
In small devices such as a personal digital assistant (PDA) it is important that a non-functional feature incorporated for security purposes not increase the bulk or weight of the device. Ideally the tamper sensing function should be provided, to the extent possible, using structure already incorporated in the device.
In a device which contains confidential data or personal information that would be useful for identity theft, the stored information should be destroyed if the device is disassembled in an attempt to access data which cannot be obtained using the legitimate access to the device.
The present invention utilizes a central screw which secures the device housing halves together as a portion of a circuit path that maintains an output node of the circuit at a ground potential. When the screw is removed to separate the housing portions and access the enclosed apparatus to obtain data from the device rather than accessing data through normal device operation using a proper password or complying with other security measures, the output node raises to a voltage level that initiates a response to the tampering. This response may be erasure of the memory or mechanical intervention that makes the device and its stored data useless.
The circuit path through the screw or bolt which secures the enclosure portions is effected by a conductor path applied to the housing surface and a compressive connector that connects the housing surface conductor path to the device ground on the printed circuit board. In many environments the enclosure members have a conductive coating applied to the internal surfaces to suppress electromagnetic interference and this provides the conductive path for the tamper sensing circuit. The tamper sensing circuit can thus be implemented using structure already present in most of the devices in which it would find use.
As shown and described, the screw or bolt which interconnects the two device enclosure portions is electrically connected to the device printed circuit board by passing through an opening in the board and engaging a connector element soldered to the board. This connector element is formed as a flat annular member with flexible or resilient fingers that extend radially inward to engage and provide electrically conductive engagement with a screw which extends therethrough and deflects the fingers. The tamper sensing circuit does not have any material effect on the size or weight of the using device and makes use of several structures existing in the device.
The screw 26 also passes through a circular opening 42 in the printed circuit board 18. Electrical contact between the screw 26 and a circuit path 44 on printed circuit board 18 is effected by a resilient metal annular member 46. As seen in
A compressible conductive part 52 is soldered to the printed circuit board and engages the upper enclosure member conductive layer 54 to provide the conductive layer 54 a connection to the card ground circuit 55. The conductive layer 54 is a circuit path extending between the conductive part 52 and the metal insert 33 to cause the screw 26 to be connected to the card ground circuit when installed to engage the threaded insert and secure the upper enclosure member 12 to the lower enclosure member 14.
Although the conductive layer 54 is shown as a circuit path applied to the upper enclosure member inner surface 56, it is frequently unnecessary to make a special provision for this conductor since it is often necessary to apply a metal coating to such enclosure member inner surface 56 to prevent electromagnetic emissions.
The length of overlap of the enclosure member marginal flanges 15 and 16 is greater than the length of screw 26 that is received in the enclosure member threaded opening 32. Thus, the screw 26 will disengage from the threaded opening 32 and signal tampering at node A before the enclosure member marginal flanges 15 and 16 cease to overlap. The existence of tampering is thereby signaled prior to access being gained to the interior of the device housing and the device circuitry.
This invention utilizes structure that already exists in the device to perform a large portion of the function. This minimizes the structure that must be added to support the sensing function. Thus, when tamper sensing is required, it can be provided with little or no impact on the device volume, which is highly restricted in most electronic apparatus environments.
The foregoing description of an embodiment of the invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or limit the invention to the precise form disclosed. Many modifications and variations are possible in light of the above teaching. It is intended that the scope of the invention be limited not by the description and illustrations, but rather by the claims appended hereto.
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4945341 | Buttimer | Jul 1990 | A |
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5656866 | Conrow | Aug 1997 | A |
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Number | Date | Country | |
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20050088303 A1 | Apr 2005 | US |