Patent Document

[0001]     This application is a continuation-in-part of the prior application by Yosef Bitton, Ser. No. 10/907,371, filed Mar. 30, 2005 (now abandoned) which is incorporated herein by reference. 
     
    
     BACKGROUND OF THE INVENTION  
       [0002]     Many individuals and enterprises that have begun accumulating significant amounts of digital information lack a reliable and convenient way to preserve this digital information in case of disaster, such as fire or flood. This digital data may include, but is not limited to, personal financial records, scanned copies of paper documents, digital photos, video, music, and other digital data. The current mechanisms for protecting this digital data are unreliable and sufficiently laborious that often this data is not protected in any way. Additionally, prior mechanisms for backing up and preserving this data often expose the backup copy to the possibility of theft or loss.  
         [0003]     Modern day businesses are moving at an ever greater pace with real-time transactions taking place at a rate in which the loss of even a few minutes worth of data can cause significant problems in recovery. Thus an active, protected computer server that has permanent and immediate survivability in the face of disaster is an ever increasing need. For example, doing periodic backups, the temporal cost of these backups is increasing such that losing a week or just a day&#39;s worth of data can prove devastating.  
         [0004]     The fundamental facility of U.S. Pat. No. 6,158,833, for example, is the dissipation of heat generated by the storage element through the use of a large enclosure. The patented system attempts to protect a specific backup storage element but it suffers from the aforementioned need to actively perform a data backup function which is required or data protection is non-existent. U.S. Pat. No. 5,623,597 has a system for protecting a data storage element. However, this active system leads to a complicated mechanism that is by nature prone to failure.  
         [0005]     In view of these and other deficiencies of the prior art, the present invention has as one object the provision of an apparatus for storing digital data that has a significantly improved ability to survive common disasters such as fire, water damage, flood, and structural destruction. Another object is to provide additional, optional mechanisms to protect sensitive information stored in the apparatus, even if the apparatus is stolen.  
         [0006]     A further object is to provide mechanisms used with data storage apparatus that are convenient enough to facilitate and even encourage the invention&#39;s use.  
         [0007]     Yet another object is to provide a data protection apparatus which employs two fundamentally different mechanisms for heat dissipation including a way of reducing power consumption during periods of low or no use which fully engages only when service is required of a user, as well as a second fundamentally different mechanism of heat dissipation.  
         [0008]     These and other more detailed and specific objects of the present invention will be better understood by reference to the following Figures and detailed description which illustrate by way of example but a few of the various forms of the invention within the scope of the appended claims.  
     
    
     THE FIGURES  
       [0009]      FIG. 1  is a diagrammatic perspective view of one preferred form of the invention partly broken away showing an external protective enclosure, an internal heat-absorbing envelope, a power and network connectivity cable and the internal enclosure containing the computer server.  
         [0010]      FIG. 2  is a perspective view of the computer server enclosure showing power, console and Ethernet connectors.  
         [0011]      FIG. 3  is a perspective view of the computer server enclosure with its associated access panels removed to reveal the internal computer server printed circuit board (motherboard or MB) and a second board which acts as a carrier for storage elements or disk drives.  
         [0012]      FIG. 4  is a top plan view of the computer server motherboard and the major components (CPU, memory, connectors) that are on the motherboard as well as four I/O interface ports and a connector for attaching a non-volatile storage element.  
         [0013]      FIG. 5  is a bottom view of the storage element carrier board showing four storage elements with their connectors and cables.  
         [0014]      FIG. 6  is a partial exploded perspective view showing the cables connecting the storage elements to the motherboard.  
         [0015]      FIG. 7  is an electrical schematic showing a battery backup circuit with battery-charging capability.  
         [0016]      FIG. 8  is a block diagram showing the principal computer server hardware components.  
         [0017]      FIG. 9   a  is a flow diagram depicting a decision tree in accordance with the invention for survivability.  
         [0018]      FIG. 9   b  is a flow diagram depicting the decision tree in accordance with the invention for power control.  
         [0019]      FIG. 10  is a diagram of the motherboard with associated mini-PCI, IDE (Integrated Drive Electronics) I/O controller used in the working example.  
         [0020]      FIG. 11  shows perspectives of the mini-PCI IDE I/O controller used in the working example.  
         [0021]      FIG. 12  shows the connections between the motherboard and storage elements via the use of the mini-PCI, IDE I/O controller and a standard IDE ribbon cable in the working example. 
     
    
       [0022]     Briefly, the invention includes an outer protective enclosure or container for a data processor, i.e. computer, that provides environmental protection from fire, water, and tampering or theft of the computer components. An external electrical connection assembly provides connectors that furnish computer network connections, peripheral connections for external devices, and power supply connections. This assembly also provides a seal to prevent infiltration of fire, water, and other environmental hazards into the protected environment. The connection assembly also can provide environmental data such as ambient temperature to the computer in the protected interior of the enclosure. This environment information may be used by software processes running on the computer components to activate additional, optional, passive and active protection mechanisms. Since power management is used to control and minimize heat generation, the heat generated is low enough that passive dissipation is sufficient and, being passive, is inherently more reliable than active dissipation techniques. We have found that passive heat dissipation (typically through two or more layers of material to the outside) is adequate if the internal temperature does not exceed operating parameters of the specific electronics that are used, for example, 30° C., i.e. 86° F. If there is insufficient passive heat dissipation, the wall thickness can be reduced or wall materials of greater heat conductivity are used.  
         [0023]     In one preferred form of the invention, provision is made for the control of heat generated by the enclosed computer components. The invention successfully dissipates small amounts of heat from within the enclosures but also protects the inside of the enclosures from extreme heat to which it may be exposed on the outside. First the heat produced by the computer server inside the enclosure is reduced to a minimum. When this is done, we have found that a heat-absorbing substance or phase-change material such as a salt or other meltable substance which is used in the enclosure does not activate and the heat is successfully transferred through the enclosures to the outside environment. In the event of a fire, however, the enclosures protect the computer server from extreme temperatures due to activation of the phase-change material. Thus, low levels of internally produced heat are dissipated through phase-change material while high levels of heat are absorbed by phase-change material as it changes from a solid to the liquid phase. The protective enclosure provides time to prevent excessive internal temperatures during a brief period of typically ½ to one hour following a fire. The actual length of time depends of several factors including the nature and amount of phase change material used as well as the size of the enclosure and its characteristics. The enclosure still, however, permits the dissipation of internally generated heat to the outside environment by conduction through the walls and a layer of phase-change material. Thus, the invention protects against a brief period of heat exposure, but during normal operation adequately dissipates internally produced heat.  
         [0024]     A digital data storage assembly that is provided as a part of the computer contains the digital data stored in the apparatus and is structured to tolerate some hardware failures so as to provide back-up storage of customer data in the event of a disaster. One preferred embodiment of this component is a RAID (Redundant Array of Independent Disks) data storage component.  
         [0025]     A digital data storage processing element provides the processing required to manage the storage and retrieval of the digital data from the digital data storage assembly, handles encryption of the data for additional protection of the data, and performs the computer network protocol processing required to accept and provide digital data to other network-attached computers. This processing element also uses environmental information, provided by sensors, to protect the digital data by active means, such as powering down components of the apparatus. This processing element also provides notification of exceptional potentially harmful conditions to remote entities using communications connections, such as a wired computer network connection, telephone connection, or a wireless computer network connection.  
         [0026]     The temperature sensors used in the invention are provided as embedded, integrated mechanisms common in many present day integrated circuits (ICs) and are part of what is referred to as “hardware health monitoring” to monitor such elements as voltage, temperature, fan RPM, etc. Monitoring can be accomplished, for example, using a suitable Intel inter IC Bus (I2C Bus) to prevent potentially harmful conditions between computer components, e.g a display or alarm. Alternatively, a Phillips System Management Bus (SMB) which is based on a I2C bus can be used. These embedded sensors and the information they provide, such as temperature, are used in accordance with the present invention to trigger an alarm or to cause the operating system (OS) to take evasive or protective action.  
         [0027]     Also, in accordance with a preferred form of the invention, a data encryption module is provided which employs suitable known methods and devices for the optional encryption of data stored within the computer server. The preferred embodiment for this assembly is a data encryption algorithm which, along with a key, transforms clear text data into encrypted data prior to its being stored in any storage elements. Upon retrieval of encrypted data from storage elements, a reverse transformation decrypts the data back to the original clear text. The storage elements can be the main storage element assembly or, if desired, a flash memory device such as Secure Digital memory cards can be used. Encryption keys can be provided manually, as will be described in more detail below, by a biometric device or resident within a flash memory device such as a Secure Digital flash memory device. When a flash memory or biometric device is used, it is preferably located inside the protective enclosure, but may also be connected through the external connection assembly so as to be located outside the enclosures, depending upon security or operational requirements. The protective apparatus provided in accordance with the invention consists of a number of components serving distinct purposes to enhance survivability and promote effectiveness and usage of the the invention. The invention thus provides an improved method and apparatus to store and protect digital data such as financial records, digital photos, scanned images, documents, and other digital data. During use the digital storage system is contained and operates within a protective enclosure that is capable of surviving fire, shock, crushing forces, submersion, and other effects of a disaster. By keeping heat production within the enclosure to a minimum, the Digital Data Storage Assembly components are able to operate properly even though enclosed and sealed. The collection of information about the external environment allows additional active protection mechanisms to be used as will be described to further enhance the Digital Data Storage Assembly&#39;s survivability. The active protection mechanisms include activation of remote alarm systems using computer network connections and activation of power management techniques to reduce heat output or system shutdown.  
       DETAILED DESCRIPTION OF THE INVENTION  
       [0028]     There are two complementary aspects to the invention; first, a mechanical aspect that concerns the hardware which is provided, and second, the method of operation which will be described following a description of the mechanical aspects.  
         [0029]     The mechanical aspects of the invention will now be described by way of example with reference to  FIGS. 1-6 . Refer first to  FIG. 1  which shows in perspective the external protective enclosure or housing such as a metal box  10  with a lid  12  shown open. The material from which box  10  is constructed provides an external protective enclosure  17   b  that is strong enough to survive crushing disasters and preferably has heat-absorbing qualities. A water-resistant or waterproof rubber or plastic seal  16  is provided for sealing out liquids, vapors, and other contaminants detrimental to an internal envelope assembly  27  and its contents. The internal envelope assembly  27  contains a heat-absorbing substance  17   a  such as a metal of high heat capacity, e.g. iron, or an enclosed salt or other meltable (phase-change) substance to absorb heat as it melts, e.g. at say about 90° F.-140° F. so as to increase the survivability of any internal components by reducing the rate gradient at which the internal temperature rises due to environmental conditions. Examples include myristyl alcohol M.P. 100° F., cetyl alcohol M.P. 120° F., and stearyl alcohol M.P. 137° F. The heat-absorbing phase-change substance  17   a  and  17   b  shown in the cut-away portions of the protective enclosure  10  and the internal envelope  27  or other heat transmissive material, e.g. a metal, acts as a conductive enclosure for transferring internal heat to the environment. Placed inside the internal envelope is a digital electronic data processor and memory such as network computer server within an enclosure assembly  15 . A power and network connection cable  14  is fed through a liquid/contaminant-resistant passage  13  and extends from the computer server out through the external protective enclosure  10  to provide power, computer network connectivity, and connectivity for sensors external to the enclosure. The front side of the internal envelope  27  can be seen through the cutout in the center of the protective enclosure  10 . A fluid level sensor  89  between the external protective enclosure and the internal envelope assembly detects flooding such as water. This information is transmitted to the computer server as detailed later. In addition, a battery backup and charger unit  100  is mounted somewhat above the internal floor of the external protective enclosure, and above the level at which the fluid level sensor activates signaling fluid contamination. Power from the external cable  14  is fed internally to the battery backup/charger unit  100  via power cable  101 . This allows the computer server within the closure  15  to shut itself off in the event external power is suspended. The battery backup/charger system is shown in  FIG. 7 .  
         [0030]      FIG. 2  is a perspective showing the network server electronics enclosure assembly  15  consisting of the network server electronics enclosure or housing  29 , the rear cover  21 , the front cover  25  and the front cover fasteners  18  which fasten the front cover  25  to the network server electronics enclosure  29 . A suitable connector mechanism is employed to fasten the rear cover  21  to the network server electronics enclosure, e.g. as shown below in  FIG. 3 . To illustrate by way of example how the invention can be used, an RJ-45 Ethernet connector  22 , an RS-232 diagnostics connector  23  and a 10 mm×2.1 mm DC power connector  24  can be seen through cutouts in the front cover  25 .  
         [0031]      FIG. 3  is an exploded perspective of the network server electronics enclosure assembly  15  with a back cover  21  and a front cover  25 , both of which have mounting holes  17  to receive fasteners, e.g. screws, to fasten the covers  21  and  25  to the enclosure  29 . The front cover  25  typically has three cutouts. A power cutout  18  allows access to the power connector  24 ; a console cutout  19  allows access to the RS-232 diagnostics connector  23 ; and an Ethernet cutout  20  allows access to the RJ-45 Ethernet connector  22 . Each of these connectors is mounted on the computer server motherboard  40 . A storage device carrier board  41  is also shown.  
         [0032]      FIG. 4  shows a top view of the motherboard  40  which, by way of example, is a fully self-contained, single-board computer with power  24 , diagnostics  23 , and Ethernet  22  connectors. Furthermore, there are main memory modules  31 , a central processing unit or CPU  30 , and four Consumer Electronics Advanced Technology Attachment (CE-ATA) ports ( 32 A,  32 B,  32 C,  32 D) which provide the motherboard I/O connectivity to storage elements  75  ( FIG. 5 ). A bank of General Purpose I/O (GPIO) pins  37  is provided for connecting sensor signals that are external to the motherboard to the CPU and operating system. Examples include the flood and power good signals of  FIG. 7 . Temperature sensors  38  are present both embedded in the CPU chip to relate the temperature of the CPU itself as well as a motherboard residing sensor for ambient and/or motherboard temperature. These sensors communicate via the aforementioned I2C or SMBus. A flash device  36  such as, but not limited to, a Secure Digital (SD) flash memory device attached to the motherboard via SD connector  35  can provide additional storage space and/or an encryption key for security. Encryption is described in connection with  35  and  36  in  FIG. 4  in order to provide data security from adversaries, the key being required in order to view unencrypted data. The operating system uses a key of 40 or more bits that acts in concert with an encryption module which employs an algorithm of well known construction, such as, but not limited to, Data Encryption Standard (DES), Triple DES (3DES), or Blowfish to encrypt and decrypt data stored in the storage elements as it is stored and retrieved. Without the key, access to decrypted data is mathematically extremely difficult. Common key sizes include 40 bits, 128 bits, 512 bits, 1024 bits and 2048 bits. 40-bit encryption provides a 1 in 10 12  chance of guessing the key; 2048 bit encryption reduces that probability to less than 1 in 2.5×10 614 . The key size and encryption algorithm chosen is dependent upon the performance needed and the level of security desired. As an alternative to a non-volatile device containing a key is that an individual or entity provides a key by entering it manually via the diagnostics port  23  or via the network connection  22 . In either case, it is the responsibility of an individual to provide and retrieve the key, be it in a flash device or manual entry. The aforementioned external connector  24  can also be seen in  FIG. 4 .  
         [0033]      FIG. 5  shows the bottom view of the storage element carrier board  41  revealing four 1.8″ CE-ATA hard disk drive storage elements  75  anchored to the storage element carrier  41 . Each storage element  75  has an integrated CE-ATA connector  74  to which a CE-ATA I/O cable is attached. The other, i.e., free ends  73  of the cables have similar CE-ATA connectors which are attached to one of the four CE-ATA ports ( 32 A,  32 B,  32 C,  32 D) on the motherboard  40  ( FIG. 4 ).  
         [0034]      FIG. 6  illustrates the cables  73  connecting the storage elements  75  to the motherboard providing I/O access and power to the storage elements  75 . Once the cables are attached between the motherboard  40  and storage element carrier board  41  and the boards are brought together, the cables  73  are sandwiched between the two. The entire assembly is then inserted into the computer server enclosure  29  as depicted in  FIG. 3 .  
         [0035]      FIG. 7  is a schematic for a battery backup and battery charger  100  ( FIG. 1 ) circuit. Power from the power and network cable  14  ( FIG. 1 ) is applied to V in  typically providing a range of 5V to 32V of DC power to voltage regulator  80 . V out  is the main power for the computer server and is connected to power connector  24  ( FIGS. 2, 3 ,  4 ). A resistor  81  is connected between voltage regulator  80  and ground by conductor  78 , and a resistor  83  is connected between conductor  78  and regulator output labeled out. Resistors  81  and  83  control and restrict the out voltage of the voltage regulator  80  to a level suitable for V out  as well as a trickle charge for a battery  85  that is connected in series with a resistor  84  between V out  and ground. A diode  82  in conductor V out  between resistors  83  and  84  prevents battery power from flowing into the voltage regulator  80  if power to V in  is removed. When power is applied to V in , the resistor  84  operates as a current limiter for a trickle charge current, as specified by the battery  85  specification, thus charging the battery  85  as well as providing power to V out . If in the case of an accident or power failure such that power to V in  is suspended, the battery  85  will supply power to V out  through a diode  86  which also ensures that only current limited with resistor  84  is available for the trickle charge of battery  85 . The presence or absence of main power is indicated by a power good signal  88  which has a current limiting resistor  87  wired between  80  and  82  so that the power good signal  88  is current-limited by resistor  87 . The power good signal  88  is connected to a GPIO input on the server motherboard  40  which then is able to monitor power. The power good signal  88 , the status of which can be displayed by a lamp or meter (not shown), remains high provided main power is present. If main power is interrupted, the power good signal  88  goes low and appropriate automatic or manual corrections can then be taken. Possible corrections or other actions are discussed herein in the description of operation section.  
         [0036]      FIG. 7  (and  FIG. 1 ) also shows a fluid level sensor  89 , wired between V out  and a flood signal wire  90  which extends outside the internal envelope  27  but is inside the external protective enclosure  10  and is connected to a GPIO on the motherboard  40  to provide a flood signal. During operation, if fluid enters the external protective enclosure  10 , the sensor  89  indicates this by asserting the flood signal via conductor  90  whereupon appropriate response actions may be taken. Possible actions are discussed below in the description of operation.  
         [0037]     The block diagram in  FIG. 8  shows the primary elements of the invention. The CPU is the core of operations which runs an operating system. Memory stores data and instructions in the execution of the operating system as well as execution of the control loops in  FIGS. 9   a  and  9   b . The multiple storage elements shown in a RAID configuration is on the right while signals from external sensors is fed to the CPU/operating system via GPIO paths.  
         [0038]     A few of the various alternatives to the preferred embodiment will now be described. The CE-ATA hard disk drives  75  are available in three different sizes, including the 1.8″ size described in the preferred embodiment; 1.0″ and 0.85″ sizes are also available yielding more power savings but lower capacities. As capacities increase, these will become viable substitutes for the 1.8″ size currently used. Furthermore, CE-ATA hard disk drives can also be replaced with some non-CE-ATA alternatives. First, Serial-ATA (Serial Advanced Technology Attachment) disk drives have the advantage of much greater storage capacity and higher performance but suffer from more power consumption and thus generate more unwanted heat. CE-ATA drives are aimed toward the consumer electronics (CE) market and thus have a different set of requirements including maximum power efficiency. However, the efficiency of Serial ATA (SATA) hard drives is increasing rapidly and thus could become a viable replacement for CE-ATA type drives with the advantage of higher capacity and performance. Second, storage elements can also be constructed of “flash memory” units of suitable commercially available construction. While these are very power efficient, they suffer from storage size limitations. Flash memory also suffers from limited read/write cycles. While the maximum number of cycles may be high, continuous writing to a specific area may render that area unwritable after the limit is reached thus rendering the entire device less usable in some cases. As an alternative to flash memory, a USB (Universal Serial Bus), Firewire (IEEE 1394), flash memory, or a hard disk drive can be used provided the motherboard is outfitted with an appropriate interface to which they may be connected. A fourth alternative is the use of IDE (Integrated Drive Electronics) hard disk drives which have been the norm for personal computers until the SATA standard was agreed upon and are being phased out of the industrial market. The latter can be used as the storage elements but they do not have hot-swap capability, use bulky and cumbersome 40 pin, flat ribbon cables and must have a discrete power connection. However, there are IDE type 1.8″ hard drives which are available.  
         [0039]     The operation of the apparatus will now be described. One major feature of the invention is the provision of power management techniques to maintain a level of heat production below that at which damaging effects occur. Excessive heat can result in a reduction in the level of effectiveness of the protective enclosure at one end of the spectrum to actual damage to the electronics at the other. While mechanisms for power reduction are well known and prolific, especially in the area of laptop/notebook computers, they are utilized to extend battery life, and due to overall laptop construction characteristics, do not function to prevent damage from heat build-up. In accordance with the present invention, heat build-up is sensed for activating processor down-scaling in which the speed of the processor is reduced, or disk drive power-down or shutdown when not needed, or alternatively “hibernation” in which the system state is stored in non-volatile storage and the power is cut. Upon returning to a normal temperature range, the computer system including boards  40  and  41  are reactivated and the original system operating state is restored.  
         [0040]     Refer now to  FIG. 4  which illustrates control mechanisms including hardware and operating system support components that include GPIO inputs  37  and temperature sensors  38  working in concert to effect power management, for example, Advanced Power Management (APM) or Advanced Configuration and Power Interface (ACPI). These components provide precise power management including, but not limited to processor down-scaling. Alternatively, the present invention provides power management such as disk drive power down as shown in  FIG. 9   b  during times of inactivity or the replacement of disk drives with other, lower power, non-volatile storage such as flash memory. Thus, the present invention will, in an emergency, reduce power consumption and thus heat generation to levels below any threshold for the trigger of the aforementioned undesired effects of heat on the computer and/or any of its components ( FIGS. 1-3 ,  9   b ).  
         [0041]     One major power management method of the invention is minimization of the power consumption by storage elements. This can range from passive management via the use of very low power, non-volatile storage such as flash memory, as well as active power management by reducing power to disk drives, for example. The use of flash memory, while minimizing heat generation, suffers from the limitation of reduced storage space and is therefore not a preferred embodiment, typically in the range of 10&#39;s of gigabytes (GB). Hard disk drives provide storage in the 100&#39;s of GB but suffer from higher power consumption.  
         [0042]     When utilizing hard disk drives (HDD), the operating system (OS) running on the processor continuously monitors environmental elements, especially temperature, via OS system calls to I2C and SMBus sensors. The electrical connections are all embedded in the ICs themselves, connected via GPIO, or mounted as discrete devices on the motherboard as shown at  37  and  38  in  FIG. 4 , and by  88 ,  89  and  90  in  FIG. 7 . While in operation but during periods of no activity, the OS preferably commands the HDD in accordance with the present invention into one of several states to reduce disk drive power consumption. Typically these states are: active/idle (normal operation), standby (low power mode, drive has spun down), or sleeping (lowest power mode, drive is completely shut down). At some future time when the activity resumes, the OS can command the drive to resume normal operation. In addition, the HDDs contain an embedded and integrated time-out switch controlled by the HDD internal circuitry. The OS controls the behavior of the HDD timeout switch by setting a timeout period in the HDD itself. The HDD will resume normal operations on its own whenever service is requested of it, thus reducing the amount of interaction required of the OS. This timeout period provided by the HDD is typically controlled by an 8-bit binary value providing for timeouts in the range of five seconds to twelve hours. This 8-bit value is communicated to the HDD by the operating system via the use of the appropriate HDD device driver system call.  
         [0043]     A further detailed explanation of the operation of the invention will now be provided. Refer now to  FIG. 8  which shows a block diagram of the main computer elements of the invention described briefly above within the enclosure assembly  15  ( FIGS. 1, 2 ), including the CPU, memory, hard disk drives, temperature sensors, network connectivity and backup power assembly. The CPU, memory, network connection, and hard disk drives which make up the computer server that the invention is used to protect is the assembly comprised of boards  40  and  41 . Computer boards  40  and  41  carry out two vital operations. First, they operate the disk drives as one or more RAID arrays thus providing the data storage function. The computer also monitors environmental, mechanical and other events that may be unsafe to make possible taking preemptive measures.  
         [0044]     Temperature sensors designated  38  ( FIG. 4 ) and  39  ( FIG. 1 ) are located both inside  38  the inner enclosure  15  and outside  39  the external enclosure  10  ( FIGS. 1, 2 ). Sensor  38  is an internal sensor which allows the computer to sense a problem due to excessive heat and take protective action as described in the flowcharts of  FIG. 9   a  and  FIG. 9   b  such as by powering down to reduce power consumption until the temperature is lowered to a safe level. The external sensor  39  ( FIG. 1 ), can detect external events such as the heat of a fire and power itself off to extend survivability. It is connected to an available GPIO via a signal wire which shares the cable passage  13  ( FIG. 1 ). In the event that a disaster involved loss of power, the battery backup system  100  ( FIG. 1 ) is added to also ensure the invention can power itself off to extend survivability.  
         [0045]      FIG. 9   a  is a flowchart in accordance with the invention of the decision tree for the disaster survivability process. Three simultaneous loops are actively monitoring the possibility of electrical, environmental, and mechanical problems that may arise. In the case of an electrical problem; the power is monitored to ensure that it is OK. Electrical components can survive harsh environments much better when powered off than when operating. In the case of a disaster such as an explosion or fire, the main power may be interrupted at which time an optional battery backup system provides power to the computer enabling it time to perform specific selected tasks including a notification process such as the actuation of lights, warning buzzers, email, etc., before eventually shutting down the system and powering off. In the event the device powers off, manual intervention is used to restart the system.  
         [0046]     The invention provides for monitoring of internal and external conditions, i.e. environmental conditions such as temperature via the second loop of  FIG. 9   a.  If any temperature sensors  39  ( FIG. 1 ) or  38  ( FIG. 4 ) indicates a temperature outside a predetermined normal range, then the notification process described above is activated. If the temperature is beyond a critical threshold, the notification process and power-off mode which prevents damage to the components is activated. An optional humidity and/or water sensor  89  ( FIGS. 2, 3 ,  7 ) is preferably included for sensing and reporting dangerous humidity conditions to the CPU.  
         [0047]     The third loop monitors mechanical damage. If one of the storage elements of the RAID array fails, the notification process is activated and the failed element is identified. The identification of the failed element can be accomplished in any suitable manner as by current consumption monitoring or other known method. After a specified amount of time has passed, e.g. 1-5 minutes, the third loop again monitors and checks for storage element failure. Once a failed storage element has been replaced, normal monitoring continues. Since this server is rendered disaster resistant, it effectively provides continuous backups in real-time. Furthermore, the use of RAID for the storage element provides protection against individual storage element failure whether they be comprised of mechanical hard disk drives or solid state devices such as flash memory.  
         [0048]      FIG. 9   b  is a flowchart in accordance with the invention of a decision tree that is provided for the management of power. Two simultaneous loops actively monitor the use of the CPU and the use of the disk drives. In the first loop on the left, via the use of APM and ACPI as aforementioned, the CPU is continuously monitored for usage. In times when it is not needed, or demand for processing is very light, the cycle time of the processor is increased. This slows the speed of the CPU thus requiring less power. Alternatively, during times of heavy processing requirements, the speed of the CPU is increased, possibly to its maximum depending on load.  
         [0049]     The second decision loop on the right monitors disk drive activity. Through the use of an operating system call (command to the hard drive) the hard drive is given a timeout value such as two minutes off time. Most modern hard disk drives have this capability. The hard drive itself then uses this timeout value and counts down to zero, resetting to the initial count upon the occurrence of any read/write or control activity. If the value zero is reached after, say, two minutes, the timeout has “expired” and the drive enters into a power-down or standby mode. Upon the occurrence of any read/write or control command, the hard drive powers-up (wakes up) and the command is completed and the timeout count is reset.  
         [0050]     The following working example further illustrates typical circuit and operational constants and components that can be used in accordance with one preferred form of the invention. Referring again to  FIG. 1  and  FIG. 2 , the external enclosure  10  can be any suitable commercially available metal storage chest. The internal assembly  27  can include a suitable commercially available meltable salt or other phase-change compound which is placed within the walls of the external enclosure  10 . The network server electronics enclosure assembly  15  is a Hammond Manufacturing extruded aluminum case P/N 1455N1601. The motherboard  40  is a PC-Engines WRAP.2C with 266 MHz AMD GEODE CPU, 64 MB SDRAM memory with one Ethernet port, two mini-PCI interfaces and one RS-232 console I/F. Power for the invention is provided by a Cincon Electronics P/N TR25050 5V/4A AC adapter  24 . The IDE I/O modules  133 A and  133 B are GlobalAmericanInc P/N 1801030 mini-PCI IDE controller boards.  
         [0051]     Refer now to  FIG. 10  which shows the WRAP.2C computer server motherbbard  140  (with memory, CPU and external interfaces similar to motherboard  40 ) with a Mini-PCI interface  132 A and a mini-PCI IDE controller  133 A. The mini-PCI IDE controller  133 A is inserted into the mini-PCI interface  132 A. This provides two IDE ports to which an IDE ribbon cable can be attached.  FIG. 11  shows top, front, edge, and off-center perspective views of a mini-PCI I/O module assembly  133 . The top view shows the circuit board  161  which has two 40-pin IDE connectors  160 A and  160 B providing mechanical access to electrical I/O ports IDE 0  and IDE 1  respectively and which correspond to I/O ports  32   a  and  32   b  of  FIG. 4 . Referring to  FIG. 12 , the storage elements  175  which correspond to storage elements  75  of  FIG. 5  are Toshiba MK5002MAL 5 GB 1.8″ 4200 RPM UDMA/66 IDE disk drives. Converter  176  is an Addonics Technologies, 1.8″ Toshiba drive to 2.5″ laptop drive interface PIN AAT18IDE25. Converter  174  is a DataPro 2.5,″ 44-pin IDE to 40 pin IDE adapter P/N 1920-00C. Cable  170  is a generic 40-pin, 80-conductor IDE flat ribbon cable.  FIG. 12  also illustrates the electrical connections necessary to allow the motherboard assembly  140  to utilize the storage elements (hard disk drive assemblies)  175 . Each storage element  175  is connected to a 1.8″ Toshiba hard drive interface to standard 44-pin laptop drive interface converter  176 . This converter is then connected by a standard 44-pin IDE laptop drive to standard 40-pin IDE interface converter  174 . In turn, the 40-pin side of each converter  174  is connected to one of the two 40-pin interfaces  173 A and  173 B of a standard 80-wire IDE ribbon cable  171  and assembly  170 . The host interface connector  172  provides the mechanical interface to one of the two IDE connectors  160 A and  160 B (in this case  160 A which is IDE 0 ) on the I/O module  133  thus showing the specific connection of storage elements  175 , via converters  174  and  176  and ribbon cable assembly  170  to IDE port IDE 0 . A second storage apparatus as just described in  FIG. 12  (not shown) can be added by attaching it to the other IDE connector, either  160 A or  160 B, whichever was not used earlier (in this case  160 B which is IDE 1 ), thus bringing the total number of storage devices  175  to four.  
         [0052]     Many variations of the present invention within the scope of the appended claims will be apparent to those skilled in the art once the principles described herein are understood.

Technology Category: g