Patent Publication Number: US-6983225-B2

Title: System and method for remotely monitoring, diagnosing, intervening with and reporting problems with cinematic equipment

Description:
PRIORITY 
     The present application claims priority to U.S. Provisional Application Ser. No. 60/435,164 filed Dec. 20, 2002. 
    
    
     BACKGROUND 
     The invention generally relates to theatres and cinemas, and relates in particular to networks of theatres and cinemas. Operational practices may vary among theatre and cinema networks and vary from screen to screen as well as vary at different times of a day, week, month or year depending on the individuals operating the equipment. As a result, inconsistencies or problems may arise. For example, start times of movies may vary (due to crowds, weather or operational difficulties), volume levels may be changed, and equipment may be inadvertently left on. 
     Equipment that is directly involved with movie presentation is generally monitored and maintained since moviegoer audiences may complain if it is not. Ancillary equipment, however, is often overlooked. As an example, pre-show advertising may be delivered by slide projectors, which are often forgotten or ignored. Routine spot checks by the screen advertising industry indicate that slide projectors have a delivery failure rate of over 10%. 
     The in-theater advertising industry depends upon statements from theaters as the sole means by which successful delivery of theater advertising is determined. Statements are generated on a periodic basis (e.g., weekly) for the purpose of reporting the successful delivery of advertising content to the theatre&#39;s patronage. Statements are sworn written statements affirming successful presentation of the movie pre-shows for a particular period of time and the patronage for that period. Typically, statements are authored by a theater manager who does not always have a first-hand account of the delivery of each movie pre-show included in the time period of the affidavit. Unfortunately, use of statements may be subject to errors and omissions. Statements often reflect 0% delivery failures, which is typically not consistent with the failure rate observed through routine spot checks. 
     In general, the theater manager may not become aware of a failure in non-movie-related equipment for many hours and often even days. Once aware of the failure, the manager has no knowledge of the length of time the pre-show equipment has been in the state of failure. Furthermore, once the manager is aware of the failure, reporting that failure to be fixed by the screen advertising company remains a lower priority than general operations of presenting movies and selling concessions. Failures do not always involve equipment breakdowns. Equipment may simply be disabled for special events or other reasons and simply not re-enabled. 
     Lack of attention to non-movie-related equipment results in extended downtime. Lack of awareness regarding non-movie-related equipment failures results in errors and omission to the statements. Actual movie start-times may vary from the schedule, which can lead to moviegoer irritation. Equipment is not always left in the proper state, which may lead to excessive wear and power consumption. 
     There is a need, therefore, for a system and method for monitoring, diagnosing and even intervening with and reporting problems with theatre and cinematic equipment. 
     SUMMARY OF THE ILLUSTRATED EMBODIMENTS 
     The invention provides a system for communicating with, and receiving data representative of equipment state and status from, movie theatre equipment in theatres. In accordance with an embodiment, the system includes a central computer storage unit for receiving and storing data representative of equipment state and status, and a plurality of remote computer storage units coupled to the central computer storage unit for transmitting data representative of equipment state and status. Each of the plurality of remote computer storage units includes a first remote computer storage unit coupled to at least one theatre automation unit for detecting and transmitting data representative of automation equipment state and status. The first remote computer storage unit is also coupled to at least one theatre projection unit for detecting and transmitting data representative of projection equipment state and status. The first remote computer storage unit is also coupled to at least one theatre audio processing unit for detecting and transmitting data representative of audio equipment state and status. The first remote computer storage unit is also coupled to at least one theatre power source for detecting and transmitting data representative of power state and status. 
    
    
     
       BRIEF DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS 
       The following description may be further understood with reference to the accompanying drawings in which: 
         FIG. 1  shows an illustrative diagrammatic view of a system in accordance with an embodiment of the invention; 
         FIG. 2  shows an illustrative diagrammatic view of a server assembly for use in a system in accordance with an embodiment of the invention; 
         FIGS. 3–5  show illustrative diagrammatic timing charts for a signal logs in accordance with various embodiments of the invention; 
         FIGS. 6–8  show illustrative diagrammatic views of operational functional views of operation stages in accordance with various embodiments of the invention; 
         FIG. 9  shows an illustrative diagrammatic view of a job scheduling report table in accordance with an embodiment of the invention; 
         FIG. 10  shows an illustrative diagrammatic view of a supporting data table for use with the table of  FIG. 9  in accordance with an embodiment of the invention; 
         FIG. 11  shows an illustrative diagrammatic view of an event report table in accordance with an embodiment of the invention; 
         FIG. 12  shows an illustrative diagrammatic view of an exposure report in accordance with an embodiment of the invention; 
         FIG. 13  shows an illustrative diagrammatic view of an event data stream table in accordance with an embodiment of the invention; 
         FIG. 14  shows an illustrative diagrammatic view of data flow during detection, interpretation and auto-correction steps in a system in accordance with an embodiment of the invention; 
         FIG. 15  shows an illustrative diagrammatic view of data flow during detection, logging, transfer and indexing steps in a system in accordance with an embodiment of the invention; 
         FIG. 16  shows an illustrative diagrammatic view of data flow during the reporting step in a system in accordance with an embodiment of the invention; 
         FIG. 17  shows an illustrative diagrammatic view of data flow at the web interface in a system in accordance with an embodiment of the invention; and 
         FIG. 18  shows an illustrative diagrammatic view of data flow at the client-server in a system in accordance with an embodiment of the invention. 
     
    
    
     The drawings are shown for illustrative purposes only and are not to scale. 
     DETAILED DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS 
     In accordance with various embodiments, the invention provides a computer-based system for monitoring the state and status of a network of geographically dispersed in-theater equipment. State and status data are collected and used in real-time or near real-time to alert operators of failures and to cause the dispatch of maintenance personnel to effect system repairs. Such failures as well as system restoration are recorded as system incidents. System incidents, in turn, are recorded in reports complete with fault assignment and operational down-time. Fault is the basis for compensation in the form of make-good and/or rebate. In the case of equipment breakdowns, these records may also serve as a basis for component performance metrics and benchmarking. 
     A goal of certain embodiments of the present invention is to maximize system availability by quickly identifying and reporting system failures thereby decreasing response and repair time, in turn, increasing system availability. The process begins when: (a) system components report specific error conditions to their respective host computers; (b) host computers lose contact with system components; or (c) host computers detect disruptive environmental conditions such as loss of power. This state and status data is relayed back to a central computer that, in turn, automatically alerts a system operator, a field maintenance provider, or in-theater staff person, thus initiating the process of system restoration. Earlier detection and intervention will result in higher system availability. 
     A further goal of certain embodiments of the present invention is to record and report the cause and fault of an incident as a basis for compensation. State and status data is the foundation for incident records that are further detailed by operators and/or field maintenance personnel. An important attribute of an incident is its fault classification, which is either implicit in the data or explicitly assigned by operators. Parties directly associated with system operations may then be held accountable for downtime. Compensation may be calculated directly from the lost opportunity on a lost time, lost CPM, or other basis. 
     A further goal of certain embodiments of the present invention is to record and report statistical performance metrics by theater for the purpose of identifying best practices as well as identifying potential theater-specific environmental threats. Each theater has the potential for maintaining smooth operations conducive to high availability. Poor operational practices or environmental issues may reduce availability. By comparing practices and environmental issues at high-availability theaters to those at low-availability theaters, best practices and best environmental conditions may be identified. Best practices and environmental conditions may then be adopted by otherwise low-availability theaters, thereby improving availability of the overall system. 
     A further goal of certain embodiments of the present invention is to record and report statistical performance metrics by hardware components for the purpose of identifying best-of-breed. Components from varying manufacturers will result in varying degrees of system availability. By identifying those models of component yielding the highest availability, the system may be scaled (extended) with best-of-breed components thus increasing overall system availability. 
     A further goal of certain embodiments of the present invention is to record and report statistical performance metrics by installation team for the purpose of identifying best equipment installation practices. Each installation team may bring individual skills and knowledge to bear on system installation. Some practices may result in higher availability, reduced time/cost per install and reduced maintenance. By identifying those practices that yield the highest availability and the lowest costs, the system may be scaled (extended) with best installation practices. 
     A further goal of certain embodiments of the present invention is to record and report statistical performance metrics by maintenance team for the purpose of identifying best maintenance practices. Each maintenance team will bring individual skills and knowledge to bear on system maintenance. Some practices may result in higher availability, reduced time-to-fix/cost and reduced repeat visits per incident. By identifying those practices that yield the highest availability and the lowest costs, the system may be maintained with best maintenance practices. 
     A further goal of certain embodiments of the present invention is to automatically attempt to self-correct certain types of failures. This includes, but is not limited to, automatically resetting equipment. In the case of a failure such as loss of network connectivity, the system may allow some time for communications to resume. In the event that communications do not resume within a pre-established period of time, the system may reset itself in an attempt to re-establish communications. This technique is not limited to internal system components, but may be employed with other devices connected to the system. Rapid, automated, self-correction techniques reduce time-to-fix, which increases system availability. Self-correction techniques also reduce cost-to-fix by eliminating labor. 
     A further goal of certain embodiments of the present invention is to serve as a platform for recording and reporting data for other in-theater devices including, but not limited to traditional 35 mm film projectors, digital movie projectors, digital movie players, audio equipment, and ancillary equipment such as film platters. Such data may be used for real-time failure resolution as well as statistical reports in way similar to the other goals of the present invention. 
     In accordance with an embodiment, a system of the invention may provide for remotely monitoring the state of movie theatre equipment. The system records status directly and/or records states and state-changes that can often be diagnosed as status. The system alerts operators to errant conditions. Operators can interrogate the database of states, status and incidents for patterns of equipment failures and equipment operational practices. The system facilitates documentation of incidents, which are equipment interventions, repairs or replacements, associated with equipment status data. Operators may correlate the data with movie showing data to reveal lost opportunities to show pre-show advertising. Operators may further correlate the data with attendance to reveal lost opportunities to show pre-show advertising on a per-impression basis. Such lost opportunities, otherwise known as miss-outs, may then be used as a basis for compensation, make-goods or reimbursements. 
     In accordance with various embodiments, sensors may be used to monitor each attribute of each piece of equipment. Data is collected from each sensor and transferred to a central location that facilitates analysis. A general architecture for such a system may include a computer at each location to log and relay data from the sensor to the central location. Transmission of the data from a set of remote theaters to the central location may involve a WAN (Wide Area Network). A central facility for collection and analysis of the data may include a relational database operating on a central computer. This architecture is highly aligned with an emerging digital screen advertising system. Furthermore, with a typical downtime of 10%, screen advertising is the biggest benefactor of remote monitoring and diagnostics. 
     Because the remote monitoring application and digital screen advertising application are so highly aligned, an embodiment of the system of the present invention leverages the digital screen advertising system as its hosting platform. The components of the digital screen advertising system may be used as components of a system in accordance with an embodiment of the present invention. 
     A digital screen advertising system that may be used with certain embodiments of the present invention has a central computer that may be used as a regional server that exchanges data with computers at one or more remote theater complexes  12  via a WAN  14 . The WAN may be formed by a variety of technologies, such as satellite or terrestrial data communications. Each remote theatre complex  12  may include a site server  16 , a local area network (LAN)  18  and a plurality of screen servers  20 . The site server  16  is the receiving computer at each theater complex; among other duties, it serves as a relay, providing a data path between the regional server  10  and screen servers  20 . The screen servers  20  serve the content they receive from the regional server  10  onto the movie screen and sound system. 
     The digital screen advertising system maybe designed to deliver audio and/or video content, particularly advertising content, to movie theater audiences. Such a system may also serve as an infrastructure for receiving system state and status data. Such data may be used for remote diagnostics and performance monitoring. Each component in the system serves a critical function and will be monitored for failure. 
     The screen server is connected to the largest array of equipment and is therefore in a position to report the majority of component state and status data. As shown in  FIG. 2 , a screen server assembly  22  may include a screen server controller  24 , an audio processor  26 , a network  28  (e.g., a LAN), a digital projector  30 , theatre automation equipment  32  and an uninterruptible power supply (UPS)  34 . Each component may be monitored through an existing connection, a new connection or an added sensor. All monitored data is subject to being logged, and logs are returned to the regional server and available for generation of an alert and/or statistical and forensic analysis. 
     The digital projector may be controlled remotely via a serial (RS232) cable or other digital connection. Through this same cable, it may be monitored for state and status information including, but not limited to, current state of operation, projector usage in seconds, lamp usage in seconds, configuration settings, and error conditions. Monitoring may be further enhanced by including a light sensor aimed on-screen to ensure that an image is, in fact, on-screen, that the image is bright enough, perhaps that it is in-focus, on-screen, and coincides with the intended image. 
     The theater automation provides state information through the use of an interface. One such interface, an activation cable, provides the screen server with information regarding the on/off state of movie projector equipment. An alternate interface provides state and status of curtain position, masking position, and house light level, as well as additional information regarding the movie projector equipment. 
     Modern audio processors such as the Dolby CP650 sold by Dolby Laboratories, Inc. of San Francisco, Calif. have digital interfaces through which state and status data may be collected. Older audio processors could be equipped with an interface to provide similar data including, but not limited to, power status, input channel selection, audio levels, and error conditions. Monitoring could be further enhanced with one or more microphones in the theater. Such microphones could monitor audio levels and provide in-theater audio to ensure that it coincides with the intended audio. 
     A UPS such as the Powerware Best Patriot 250 sold by Powerware Corporation of Raleigh, N.C. may be used to continue to provide power to the screen server in the even of power failure. Such a device also provides power status to the screen server, notifying the screen server of power failures and preparing the screen server for possible shutdown when the reserve power in the batteries becomes low. This and similar devices may also report other power issues such as surges and brownout conditions. Power on/off and quality data is basic to equipment operation. Monitoring could be enhanced with one or more additional power sensors, in particular, sensors for detecting reflective harmonics in the power line. Reflective harmonics are high frequency currents often emitted by power supplies and may be harmful to computer electronics. The lamp house of the film projector is equipped with a particularly large power supply. 
     Network availability is tested by way of the network interface card (NIC) or similar data communications device. Not only can local/internal tests run on the device, but connectivity to other network devices may also be tested. In this way, a screen server not only reports on its own network status, but also reports on the status of other devices on its network. 
     If the network is down and if the network is not redundant, the screen server will not be able to report its own failure in real-time. One or more proximal screen servers however, which have not lost general connectivity, will report a loss in connectivity with their peer. Furthermore, the screen server with a loss of network connectivity will log the failure to be reported once connectivity is restored. In other embodiments, a redundant network may be employed. 
     The system of the present invention not only detects, logs and reports error conditions, but also non-error conditions. While the goals of the system are related to error conditions, non-error conditions often provided clues to error conditions as well as verification and auditing of non-error conditions. All data, error-related or not, is returned to the regional server where statistical and forensic analysis may be performed. 
     The regional server is a larger computer or set of computers with relational database(s), business processes and an operational interface. The regional server stores the logged data in such a way that it is associated with a particular device or set of devices and time. The regional server has an interface that facilitates display of the logged data. 
     In general, errors and non-errors are referred to as signals and signals may be presented linearly according to time as signal log timing charts as shown in  FIG. 3 . Each of a number of signals may be logged and reviewed by the system operator. In particular,  FIG. 3  shows a UPS power restore signal  40 , a UPS battery normal signal  42 , an operating system signal  44 , a monitor process signal  46 , a daemon process signal  48 , a player process signal  50 , a network ready signal  52 , a player playing signal  54 , an activation signal  56 , a projector lamp signal  58 , a show time signal  60 , and a show start/stop signal  62 . The use of a timing chart may be useful in identifying originations of problems and sequences of related failures. Signals are typically two-state, on or off, up or down, activated or not activated, etc. However, a signal could have more than two states. A tri-state signal (e.g., low, medium, high) may be presented graphically through the addition of a third middle level in various embodiments. In further embodiments, the signal could be scalar. Scalar data could be normalized to values from 0 to 1 and represented by corresponding levels from bottom to top. High-resolution data could be abbreviated in this way, but meaningful interpretation might require an alternate or supplemental data presentation form. 
     As shown in  FIG. 4 , a signal log timing chart may be viewed for a plurality of cinemas, each of which provides a cinema signals  70 – 82  as shown. The log may also include an additional site signal  84 . A further signal log timing chart may show an operating system signal  90 , a monitor process signal  92 , a daemon process signal  94 , a network ready 1 signal  96 , and a network ready 2 signal  98 . 
     The log signal timing charts illustrate how signals often operate in patterns. It is when the pattern breaks that there is usually an error condition. Signals may be view in any number of ways.  FIG. 3  shows multiple signals at a single screen server location over a three day period (Dec. 11, 2002 to Dec. 13, 2002, inclusive) as shown in the date field  64 .  FIG. 4  shows one signal from each of multiple screen servers within one location for a three day period (Oct. 9, 2002 to Oct. 11, 2002, inclusive) as shown in the date field  86 . In alternate embodiments, presentations need not be graphical, but could be textual. 
     Site servers serve largely as passive relays. As such, a site server is not typically directly connected to any array of equipment as are the screen servers. Nevertheless, a site server performs network connectivity signal reporting on both the local and the wide area networks for example, for a two day period (Jan. 26, 2002 to Nov. 28, 2002, inclusive) as shown in the date field  88  in  FIG. 5 . Similarly, the Regional Server reports only connectivity to the sites. 
     Error detection may occur local to the source, at a peer or other network device in the path to the Regional Server, or at the Regional Server. When an error condition is detected at the screen server, a local process will initiate one or more actions including but not limited to (1) recording and reporting the condition to the central regional server and (2) attempting to fix the problem automatically. 
     Error conditions are recorded in log files that are transferred via LAN to the site server then relayed by the site server via WAN to the regional server. The regional server reads and inserts the log data into its database. Along the way to the database, processes analyze the logs and flags undesirable conditions (errors and warnings) as an indication of alert status. Flagged data is displayed on an operator&#39;s console for immediate attention. Alternatively or in parallel, the flagged data is transmitted to an alternate device including but not limited to an email inbox, a mobile personal pager, PDA or text-messaging cell phone. An alternate transmission means could incorporate a wireless technology such as WIFI standard device or BLUETOOTH standard device from the site server at the theater to a communication device monitored by theater personnel. 
     As generally shown in  FIGS. 6–8 , a system in accordance with an embodiment of the invention may resolve a wide variety of failures. For example, a system in accordance with an embodiment of the invention may include a digital projector  100 , a screen server for screen x  102 , a regional server  104 , a system operator  106 , inventory  108  and a field service support unit  110 . Certain error conditions may be fixed automatically. Such an error may be caused when a device hangs or otherwise becomes unresponsive. In such cases, the screen server will reset the device as a means of attempting to clear the error. Attempts to restore device functionality are logged and transmitted to the regional server to be recorded. Once in the central error queue, an operator will be alerted. For example and with reference to  FIG. 6 , during use, a lamp failure signal  112  may be transmitted from the digital projector  100  to the screen x screen server  102 . A lamp failure at screen x signal  114  may then be transmitted from the screen x screen server  102  to the regional server  104 . A lamp failure at screen x signal  116  may then be transmitted from the regional server  104  to the system operator  106 . 
     An operator is alerted to the error condition through the operator interface or in some other electronic way such as an email sent to a personal digital assistant (PDA), cell phone or paging device. The operator will review the error condition and may review logged events before and after the error condition started. The operator may also contact the theater and request additional information. Once the operator has affirmed the error condition, he or she will create an incident record. The incident record will be associated with the error condition data through period of time and location identifier. As shown in  FIG. 7 , reviewing and incident reporting signals  118  may pass between the operator  106  and the regional server  104 . 
     The operator may then initiate a service call. Additionally, the operator may also initiate shipment of component(s). As shown in  FIG. 8 , a shipment of one or more components (e.g., a new lamp) may be made as shown at  120  following verification with the regional server  104  as shown at  122 . Field service personnel may then be dispatched to go to the digital projector as screen x  100  as shown at  124  following verification with the regional server  104  as shown at  126 . The email order identifies the required component, ship-to address and ship method. Enhancements facilitate a shipping label to be automatically printed and affixed to the order as well as a return shipping label for cases in which equipment should be sent back to the manufacturer or to a depot for evaluation and/or repair. 
     All communications are captured in the system. Anywhere possible, communications are electronic. For example, the operator&#39;s initiation of the field service call is facilitated through interaction with the operator&#39;s interface. The system then sends the service request electronically. This process has three major benefits: (1) the message is accurate and complete; (2) automation reduces labor cost; (3) transmission of the message is recorded and time-stamped within the system, thus making the incident fully auditable. 
     Receipt of the message is acknowledged by the field service provider and/or by the inventory shipping facility through a similar and automated process. This can be facilitated in a number of ways. First, email messages can be sent return receipt requested, which would cause automatic acknowledgement. In the case of field support using a PDA, pager, or cell phone, receipt can be acknowledged manually through two-way messaging using keywords that can be read automatically by the system or through a web interface, mobile (PDA, cell) or otherwise. All acknowledgements are recorded, time-stamped, and indexed with the appropriate incident record by the Regional Server when received. 
     The process is complete when the field service provider notifies the system operator that the error condition has been fixed. The operator documents any necessary final notes then closes the incident. 
     Some incidents need not be initiated by an operator, but can be initiated automatically. When a bulb fails, no investigation is necessary. The system can automatically initiate creation of an incident and request shipment of a bulb. Receipt of the new bulb may not be acknowledged, but restored operation of the projector implies resolution of the incident and the record is automatically closed. 
     Reports are typically generated for one of two reasons, accounting or performance review. Assuming that not every show will be successfully delivered, the question becomes one of monitoring the magnitude of loss, overall and by contributing party. Parties involved with the system will each account for some lost opportunities to show content. This includes, but is not limited to, the exhibitor theater staff, installation crew, maintenance crew, software development and operations, hardware manufacturer, and content provider. 
     The job scheduling report (JSR) is the top-level accounting report. Each job scheduling is a convergence of a job and a pre-show opportunity. As shown in  FIG. 9 , a job scheduling report may include a category of complete instances as shown at  130 , and a category of incomplete instances as shown at  132 . Instances are complete when the job was presented at the scheduled pre-show opportunity. Instances are incomplete when the job was not presented at the scheduled pre-show opportunity. The job scheduling report also includes a category named incomplete breakdown as shown at  134  that includes exhibitor data, hardware data, software data, content data, bugs data, installation data, maintenance data and unknown data. The incomplete breakdown category  134  is a categorization of incomplete schedulings by fault category. Fault category is indicated explicitly by an incident or implicitly by system state. The JSR lists schedulings as an actual number as well as a percentage. In this way, the system of the present embodiment contributes data to the screen advertising system in an integrated way and significant areas for compensation and/or improvement become apparent to the viewer. 
     While the JSR displays success and loss on a per job/show basis, not all shows are considered equal. The more patrons in the show, the more valuable the show is considered to be. This is because the goal of the advertising job is to reach as many patrons as possible and some shows have more patrons than others. Each instance of an advertising job that is presented to a patron is considered to be an impression. Impressions are measured in units of one thousand (1,000), the cost of which is referred to a cost per thousand (CPT). With the box-office ticket sales data, this report may also be adjusted for number of patrons. In this way, lost opportunities may be displayed on an impression basis and make-goods or reimbursements may be analyzed on a CPM basis. 
     Each actual value in the JSR is hyperlinked to its supporting data. For example,  FIG. 10  shows supporting data for a plurality of shows (as shown at  140 ) that have had errors. The reason for the error is shown at  142  and the table provides the breakdown data for the incomplete breakdown  134  shown in  FIG. 9  for each of the shows  140 . Supporting data is the list of incidents or error condition responsible for the missed pre-show opportunities within each cell of the table. Each incident can be responsible for 0 or more job scheduling failures. 
     Each incident or error condition can, in turn, be browsed to reveal specifics of the event in an event report table as shown in  FIG. 11 . Each event is identified by a site  150 , screen  152 , a start date  154  and a duration  156 . Each incident is typically assigned a fault classification. In this way, missed schedulings for a particular incident contribute to the statistics in the JSR. The event report table also identifies whether the event was resolved  158 , the impact  160 , the component  162  and the fault class  164 . Messages  166  and notes  168  are also provided as well as an identification of the shows that were impacted  170 . 
     Incidents and incident management are a means by which management may reduce lost opportunities to display pre-show content. It is, however, the content that is the revenue generator. Therefore, reports must also reveal lost opportunities on the basis of an individual piece of content (job). The advertiser cares little about the number of scheduling opportunities lost at a site; however, the advertiser most definitely cares about the successes and losses related only to their job(s). 
     Integrating job scheduling data with the exposure reports of the digital advertising system facilitates reports detailing lost opportunities.  FIG. 12  shows an exposure report for a particular job  180  assigned to a client. The report includes the show  182 , the show date  184 , the show time  186 , the show miss reason  188 , the movie  190  and the release  192 . In the case where a job was sold based on a flight of showings, this report becomes the accounting basis for a make-good. 
     The processes of the system of the present embodiment perform the following tasks: detection, logging, transfer, indexing, interpreting, alerting, auto-correction, and reporting. Detection is the process of sensing the current state, status, condition, or activity of a device. Logging is the process of storing the status along with time/date, location, device ID. Transfer is the process of moving the log data to the central server, typically by way of the Site Server. Indexing is the process of recording the data into a database according to time/date, location, and device ID. Interpreting is the process of comparing the data to conditions known to be errors. The process of alerting is to construct an electronic message to be read by a person. The process of auto-correction attempts to reset equipment if possible. The process of reporting is the presentation of data organized for statistical analysis or forensic study. 
     The system of the present embodiment collects and logs errors as well as polls for state and status at regular intervals. This collection and logging is performed at the Screen Server or equivalent. Each monitored device is connected in some form or fashion to the Screen Server or its equivalent. Monitored components include, but are not limited to, the digital projector, theater automation, uninterruptible power supplies, and network. 
     The digital projector is connected to the screen server in two ways, the first is the video cable which provides the projector with the video signal to be rendered onto the screen. The second connection is a serial control cable. Through this cable, the screen server is able to turn the digital projector on and off at appropriate times. It is also through this cable that the digital projector provides state and status information. 
     State and status of the projector include, but are not limited to, on or off and with-error-condition, with-warning-condition, fully-operational. Error conditions include, but are not limited to, lamp failure and critically high operating temperature. Warning conditions include, but are not limited to, lamp age and excessive temperature. 
     State and status data is recorded during normal state change activities such as starting and stopping the pre-show, is recorded at the time of unexpected state change events such as loss of power and is recorded at regular intervals such as every 60 seconds. 
     State and status data is logged as an event stream with time stamps for each event. Log data may not always be in human readable format and is rarely isolated to the status of just one device. For illustrative purposes, however,  FIG. 13  shows what an event data stream may look like, with date  194 , time  196  and messages  198  listed in a streaming fashion. 
     During use, a screen server  200  may perform detecting  202 , interpreting  204 , logging  26 , transfer  208  and auto-correction  210  as shown in  FIG. 14 . The screen server  200  receives an input signal  212  from a digital projector  214 , and also receives input signals  216 ,  218 ,  220  and  222  from theatre automation equipment  224 , a power supply or UPS  226 , a network interface  228  and an audio processor  230  respectively as shown in  FIG. 14 . The signal  212  from the digital projector  214  indicates that the signal is undesirable. All the signals are interpreted, and the signal  212  generates an auto-correction. Auto-correction will attempt to reset the device or otherwise clear the undesirable condition. As shown in  FIG. 14 , the auto-correction system is attempting to correct the undesirable condition by sending a reset signal  232  to the digital projector  214 . 
     Another example of an error could be a loss in network connectivity. If the network is down for more than a pre-specified tolerance of time, the auto-correction process may attempt to reset the network interface card (NIC) by rebooting the host computer. The auto-correction process may try to reset the host computer periodically, perhaps once per day, until connectivity is re-established. 
     If, in the last example, the NIC has stopped working, signals from the effected screen server would never reach the regional server. The condition however, will be recognized by one of the peer computers. Once a computer looses contact with a peer, it will log and transfer the status data back to the regional server, which will interpret the data and issue an alert. 
     The theater automation is connected to the screen server or its equivalent by means of an activation cable. The activation cable is packaged as a 110 volt AC plug connected via digital cable to a game port connector (DB15). Inside the 110 volt AC plug is a circuit which when energized by 110 volt AC closes contacts. The contact closure can be read by the screen server or its equivalent as a game port button one down event. In this way, the screen server can detect power to the activation cable. The activation cable is plugged into a 110 volt AC outlet which is controlled by the automation. When the automation detects that the feature film projector has shut down, it energizes this 110 volt AC outlet. When the automation is triggered to begin the start of the movie, it de-energizes this 110 volt AC outlet at the same time that it turns the feature film projector on. By monitoring the game port button one, the screen server can not only control the state of pre-show, but also monitor the state of the auditorium. The automation data is logged in a way similar to the digital projector data. 
     The next generation of digital automation interface (DAI) provides much greater state monitoring. The digital automation interface is a circuit that controls and monitors many aspects of the state of automation including, but not limited to, screen masking position, house light level, and fire alarm status. The screen server or its equivalent will collect this data as a means of increasing the scope of in-theater equipment monitored. 
     The network is monitored primarily through attempted to communicate with other network devices. The UPS is monitored for power and battery status. Each of these devices can be listened to or polled for state and status data. Like the digital projector and the DAI, data is time-stamped and logged in a file. 
     The audio equipment is not currently monitored, but could be monitored using a similar mechanism. Interesting data would include input, output, and volume settings as well as other configuration settings. Like the other monitored devices, data would be collected, time-stamped and logged. 
     In the case lamp failure, the alert process will tolerate several instances of failure in a row, recognizing that the screen server will continue to try to ignite the lamp. When the logs indicate that the lamp did not ignite after several attempts, the lamp is assumed to be in failure and the alerting process generates an alert. 
     In the case of the excessive activations, the alerting process will again tolerate one or more isolated instances of deactivation and reactivation as noise. However, when a threshold number of cycles is reached within a short period of time, the alerting process will interpret this as an implicit error condition and generate an alert. 
     Signal data is logged and transferred to the regional server, which would interpret the condition and could issue an alert. Alerts are issued when auto-correction fails or when auto-correction is not an option. As shown in  FIG. 15 , communications between a screen server  240 , site server  242  and a regional server  244  may involve the detecting, logging and transferring of data. For example, the screen server  240  may include a detecting unit  246 , an interpreting unit  248 , a logging unit  250 , a transfer unit  252 , and an auto-correction unit  254 . The site server  242  may also include a detecting unit  256 , an interpreting unit  258 , a logging unit  260 , a transfer unit  262  and an auto-correction unit  264 . The regional server  244  may include an auto-correction unit  266 , a detecting unit  268 , a logging unit  270 , a transfer unit  272 , an interpreting unit  274 , an alerting unit  274 , an indexing unit  276 , and a reporting unit  280 . As shown for example, error detection data may flow from the detecting unit  246  of the screen server  240  to the logging unit  250  and in turn to the transfer unit  252 . Error detection data also may flow from the detecting unit  256  of the site server  242  to the logging unit  260  and in turn to the transfer unit  262  together with error data from the transfer unit  252  of the screen server  240 . The combined error data may then be transferred from the transfer unit  262  of the site server  242  to the transfer unit  272  of the regional server  244 . Error detection data may also be transferred from the detecting unit  268  of the regional server  244  to the logging unit  270  and in turn to the transfer unit  272 . The combined error data may then flow to the interpreting unit  274  and then the alerting unit  274  as well as to the indexing unit  276  as shown. Error data may then be transferred from the indexing unit  276  to the database  282  as shown. The screen server  240  will return most of the data regarding state and status of equipment. All computers can return at least network and power status data. Status data is ultimately indexed into the database. It is also subject to interpretation by the interpreting process and subject to alerting if it matches a condition known to be undesirable. As shown in  FIG. 16 , reporting data may then be transferred to the reporting unit  280  of the regional server  244 . Alerting may take the form of a simple electronic notification and it can additionally take the form of request for service and/or request for equipment. 
     The alerting process is not limited to a single stream of signal data, but can also analyze multiple heterogeneous streams from the same screen server assembly. The alerting process can similarly analyze multiple homogeneous streams from a plurality of screen server assemblies. In this way, it can identify error conditions more specifically or more comprehensively. 
     An example of heterogeneous data analysis is the comparison of activation signal data to show schedule data. If the screen server assembly is not activated consistent with the show schedule for that cinema, then an error is indicated and an alert is generated. 
     Implicit error conditions are discovered by a pattern matching process that seeks breaks in the pattern of operation by show, by day, and by week. A break in the pattern is then compared to a set of know error condition patterns. If the process finds a match, then the pattern anomaly is alerted and identified. If there is no positive comparison, the pattern anomaly is alerted and flagged as suspect. 
     Some patterns, such as a network or power outage, can be present at more than one screen server or site server. In such cases, the pattern matching process will look for the same anomaly among its peers. 
     Indexing is the process of storing status data in the database along with the time/date, location and device identification. In this way, it can be retrieved and or sequenced as part of a query by device, by location and/or by date. With data and location, it can also be cross-correlated with show data that is part of the digital screen advertising system. 
     Electronic notification is issued primarily through email. The email is addressed to the person/party on record with the system for a particular error condition at a particular location. The subject and body of the email will address the nature of the condition detected. The body of the email may also include recommendations to correct the condition. For example, in the case where the power has gone off, it may instruct the recipient to restore power, check the circuit breaker on the UPS, check that the UPS is plugged-in, check the circuit breaker to the outlet which powers the UPS. Email can be sent to a standard email address; therefore, alerts can be sent to any cell phone, PDA, or handheld device that accepts email. 
     Electronic notification need not be email. Whether email or some other protocol or technology, the message can also initiate a service call and/or initiate the shipment of replacement parts/equipment. For example, if a bulb fails in a projector, the alert can cause a new bulb to be shipped to the location as well as an alert to in-theater personal to replace the bulb when the new one arrives. 
     Once the data has been loaded (indexed) into the database, it is available for reporting. If the database is relational, then SQL can typically be used to select ordered subsets of data for the purpose of statistical, trend and forensic analysis. 
     Alerts are error conditions that require operator attention and very likely require a field service call. Alerts are posted in an alert queue. The alert queue is visible to and monitored by operators. The alert is typically the starting point of an incident. 
     An operator will review an alert and may call the theater staff for further information. In the case of loss of connectivity the operator might ask “Did the equipment loose power?” If so, the operator would work with the theater staff to reestablish power. If not, the operator would begin troubleshooting the network and/or Screen Server PC itself with the theater staff as the eyes and hands. If the problem can be solved quickly over the phone, then the operator will document the call with the alert condition as a resolved incident. If the operator is unable to resolve the error condition with the theater staff, then the unresolved incident is documented with the alert condition and a service call is issued. 
     Some alert conditions bypass the operator and go straight to service call. This includes, but is not limited to, a lamp failure. Lamp failure is automatically interpreted as an alert condition requiring a service call. An unresolved incident is automatically created and a service call is issued by the service call process. 
     The preferred method of the service call is issued through electronic messaging. Email is used, but any electronic messaging system could be used. Emails are sent to the field service personnel specific to the region in which the equipment failure occurred and specific to the type of equipment that failed. Emails are received in a typical mailbox or, more appropriately, through wireless portable devices such as text-pagers, personal digital Aassistants (PDAs) and text-messaging capable cell phones. 
     Receipt of the electronic message is acknowledge either automatically through a return receipt request, or manually through an operator generated response. The response contains the unique incident identifier that is automatically read by an inbound message indexer, which adds a record of receipt to the incident stored in the database. 
     Once the service call has been completed and the error condition is cleared, then the service provider will close the incident by sending an electronic message containing the unique incident identifier and a keyword, cleared. The inbound message indexer will record receipt in the database and will change the state of the incident to be closed. Alternatively, the service provider can modify the incident directly through the web interface or can contact a system operator to do the same. 
     In some cases, such as a failed lamp at a remote location in which the theater staff is also the service provider, a new lamp will be shipped overnight to the theater. Shipment is assisted by the service call process, which notifies the theater staff of the incident and that a new lamp should be expected the next day, but also notifies the warehouse with a message that include the ship-to contact information. 
     There is always the possibility in an automated system that an incident will get lost or forgotten. To safeguard against this, an aging process will review unresolved incidents daily and will alert operators to any incidents that have not been attended within a preset period of time. 
     An incident is a record of a condition that required external intervention on the system. An incident is often created automatically such as in the case of a bulb replacement. However, incidents are also created manually, particularly in cases that require troubleshooting. An incident includes, but is not limited to, a start time, and end time, and error condition, and a resolution. Additionally, incidents almost always have a fault classification. Incidents record each step in the process of resolution including, but not limited to, alerts issued to service personnel, responses from personnel, equipment shipping requests, and help desk entries. 
     Reports are the result of selection and presentation of data. Relational databases typically have a query language such as SQL for accessing and sorting data according to specific attributes. The four primary attributes of the data collected by the system of the present invention are time, location and device identifier and device state. Selecting data limited to a single device and condition then sequencing according to time, one may observe the changing states of that device. Basic interpretation of the data is confirming that the states change as anticipated and flagging discrepancies. Similar analysis can be done by location. By storing the data of the system of the present invention in association with the data of the screen advertising system, discrepancies in the patterns can be associated with specific failures to deliver content (advertising jobs). 
     Should the digital advertising system be connected to the theaters point of sale ticket sales system (POS) and be collecting show time information from the POS, then the system of the present invention may compare actual equipment status with expected equipment status based on the start times indicated by the data from the POS. 
     The interface for the system of the present invention has two forms, email and direct interface. Email is used primarily for alerting while the direct interface is used primarily for signal analysis, incident management and reporting. 
     The direct interface takes the form of a web interface to facilitate ubiquitous access by all interested parties as well as facilitate frequent updates to the software without requiring the distribution and installation of updated client software.  FIG. 17  illustrates the web and application servers servicing requests from a web client on the internet. As shown, the interface includes the internet  300 , the web client  302 , the regional server  304 , the screen server  306 , the site server  308  and the database  310 . The regional server  304  includes a web and applications server unit  312 , an incident management unit  314 , a reporting unit  316 , an indexing unit  318  and an alerting unit  320 . The web and application services interact with the database through business logic processes, in this case, incident management processes and reporting processes. As shown, communications and data may flow from to and from the internet  300  to the web client  302  and the regional server  304 . Data may also flow between the web client  302  and the regional server  304 . Within the regional server  304 , data may be transferred between the web and applications server unit  312  to and from each of the incident management unit  314  and reporting unit  316 . Data may also be transferred to and from the database  310  to and from each of the reporting unit  316  and the incident management unit  314 . 
     An alternate system and method for the present invention could be characterized as a stand-alone embodiment. In such an embodiment, the equipment may be installed specifically for the purpose of detecting and reporting error conditions with equipment in the field. Signal data may be captured by one or more computers connected to remote devices. Economics would most likely dictate a single computer, comparable to a site server, for the purpose of logging and transmitting signals and error messages back to the regional server or its equivalent. The site server or its equivalent could be directly connected to monitored equipment or could receive data via LAN from special purposed devices for the purpose of detecting and relaying state, status, condition, and activity data from the theater equipment. 
     The theater equipment need not be related to screen advertising, but could include state and status data of other equipment including, but not limited to, film platters, feature film projectors, feature digital projectors and supporting electronics. 
     Special purposed equipment can also serve as a means for resetting equipment in an attempt to clear an error condition. The rules of automatic equipment resetting could be part of the special purpose device or could be in the screen server or its equivalent in which case, the screen server or its equivalent would direct the special purposed device to reset the errant equipment. 
     The screen server could be replaced by a network bridge/router device that could relay data directly back to the regional server or its equivalent. In this scenario, there would be no general purpose computer at the theater site. Rather, the theater site would be equipped purely with special purpose detection devices that are network-enabled as well as with a router/bridge device to relay data from the special purposed detection equipment back to the regional server or its equivalent. Such a solution suggests a simple communications protocol such as SNMP. 
     The screen server could also be replaced with a data file storage depot. Such a depot would be a general purpose computer or PC connected to the WAN and to the LAN. It would serve as the intermediary transport device, queuing outbound data files for transport over the WAN, especially when the WAN is satellite-based, but equally relevant when the WAN is terrestrial-based. Inbound data files received from the WAN are staged until a screen server or its equivalent or a special proposed device picks it up. 
     The interface of an alternate system could be client-server system as generally shown in  FIG. 18 . Such a system may involve data flow directly between an application client  330  and an incident management unit  332  and a reporting unit  334  of a regional server  336 . The regional server  336  also includes an indexing unit  336  and an alerting unit  338 , and is connected to the application client  330  via a local area network. The system further includes a screen server  340 , a site server  342  and a database  344  that communicated with the incident management unit  332  and the reporting unit  334  as shown. In this case, communication is facilitated over the local area network (LAN). The client software is custom software that accesses the business logic on the server, which in turn accesses the data in the database. The business logic in this three-tier application could reside in a transaction server or other type of application server. Many database management systems include a business logic layer which could also harbor the incident management and reporting processes. Finally, in a two-tier architecture, the business logic would be resident in the application client. 
     Those skilled in the art will appreciate that numerous modifications and variations may be made to the above disclosed embodiments without departing from the spirit and scope of the invention.