Patent Application
20130338543
The present application relates generally to patient monitoring. It finds particular application in conjunction with detecting patient deterioration, and will be described with particular reference thereto. However, it is to be understood that it also finds application in other usage scenarios, and is not necessarily limited to the aforementioned application.
Vital signs acquisition for patients is typically performed at periodic intervals, such as every few hours, by clinicians. The frequency depends on the severity of a patient and the resources of the treating medical institution. As healthcare costs and global competition have increased over the years, medical institutions have been forced to implement cost saving measures. These cost saving measures include caring for more patients than have been cared for in the past, reducing staff, replacing staff with less educated and/or less qualified personnel, transferring patients from the intensive care unit (ICU) to the general ward earlier than has been done in the past, and so on. The net effect is that medical institutions are unable to physically gather vital signs from patients as frequently as they once were and are becoming increasingly dependent upon patient monitoring systems to acquire vital signs. Patient monitoring systems are typically worn by patients and/or placed at patient bedsides and acquire common physiological data, such as pulse oxygen saturation, temperature, electrocardiography (ECG), and the like.
One problem with placing reliance upon patient monitoring systems to acquire vital signs is that the vital signs may be unreliable. Measurements may be skewed and/or distorted by movement artifacts and/or from not knowing conditions when the measurements were taken. For example, vital signs may be skewed and/or distorted depending upon whether a patient is resting or walking Another problem with placing reliance upon patient monitoring systems is that current systems do not evaluate vital sign measurements collected during the interim between attended vital signs acquisition for patient deterioration. Attended vital signs are vital signs obtained with the supervision of a clinician, whereas unattended vital signs are vital signs obtained without the supervision of a clinician. As a result, patient deterioration may not be recognized early enough to intervene in a timely manner. Yet another problem with placing reliance upon patient monitoring systems is that they may become disconnected from other supports systems of a typical medical institution, such that the ability to alert caretakers of deterioration is diminished and/or disabled.
The present application provides a new and improved systems and methods for detecting patient deterioration which overcome the above-referenced problems and others.
In accordance with one aspect, a deterioration detection system for detecting deterioration of a patient of a medical institution is provided. The system includes one or more processors programmed to receive attended physiological data for a patient. The attended physiological data includes automatically or manually collected measurements of physiological parameters of the patient and, in certain embodiments, manual assessments of physiological parameters. The processors are further programmed to obtain a patient score for the patient from the attended physiological data and a scoring table and receive physiological data, including at least one of unattended physiological data and attended physiological data, for the patient. The physiological data includes measurements of one or more of the physiological parameters of the patient. The processors are further programmed to compare the measurements of the physiological data to corresponding measurements in most recent attended physiological data using the scoring table to determine any change in the patient score. Even more, the processors are programmed to notify a clinician of patient deterioration in response to a physiological parameter of the physiological data deteriorating as compared to a corresponding physiological parameter in the most recent attended physiological data.
In accordance with another aspect, a method for detecting deterioration of a patient of a medical institution is provided. Attended physiological data for the patient is received. The attended physiological data includes automatically or manually collected measurements of physiological parameters of the patient and, in certain embodiments, manual assessments of physiological parameters. A patient score for the patient is obtained from the attended physiological data and a scoring table, and physiological data, including at least one of unattended physiological data and attended physiological data, for the patient is received. The physiological data includes measurements of one or more of the physiological parameters of the patient. In other words, the physiological data typically includes measurements for a subset of the parameters of most recent attended physiological data. The measurements of the physiological data are compared to corresponding measurements in the most recent attended physiological data using the scoring table to determine any change in the patient score. A clinician of patient deterioration is notified in response to a physiological parameter of the physiological data deteriorating as compared to a corresponding physiological parameter in the most recent attended physiological data.
In accordance with another aspect, a method for verifying deteriorated unattended physiological data for a patient is provided. The deteriorated unattended physiological data, including measurements of one or more physiological parameters of the patient, is received. In response to intermittently receiving unattended physiological data, a patient monitoring system is controlled to take additional measurements of at least one of the physiological parameters a predetermined number of times in one or more predetermined intervals. Further, supplemental unattended physiological data is received for the patient, including the additional measurements. In response to continuously receiving unattended physiological data, measurements of at least one of the physiological parameters are captured a predetermined number of times in one or more predetermined intervals. The measurements of the deteriorated unattended physiological data are compared to corresponding measurements of the supplemental unattended physiological data or the captured measurements.
One advantage is that patient deterioration can be detected in real time.
Another advantage is that patient deterioration can be detected from trend data.
Another advantage is that patient deterioration detection is event based.
Another advantage is that medical institutions can reduce the frequency with which caretakers manually acquire vital signs from patients.
Another advantage is that workflows of medical institutions are improved.
Another advantage is that patient safety is improved.
Still further advantages of the present invention will be appreciated to those of ordinary skill in the art upon reading and understand the following detailed description.
The invention may take form in various components and arrangements of components, and in various steps and arrangements of steps. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the invention.
With reference to
The patient monitoring systems 102 obtain unattended physiological data for patients (not shown) cared for by the medical institution. Unattended physiological data is obtained automatically without the supervision of a clinician and is indicative of measurements of physiological parameters (or vital signs) of the patients, such as heart rate, temperature, blood oxygen saturation, and the like. It is any timely ordered random sequence of measurements. Typically, each of the patient monitoring systems 102 is associated with, and obtains unattended physiological data for, a single patient, but patient monitoring systems associated with multiple patients are contemplated. The unattended physiological data is typically obtained continuously or intermittently. When the unattended physiological data is obtained intermittently, events trigger the acquisition of the unattended physiological data. Events include, for example, timer events (for periodic acquisition), manually triggered events, asynchronous events, network events, and so on. A network event is an event from a component of the IT infrastructure 100, such as the deterioration detection system 108, which triggers the acquisition of physiological data from the patient monitoring systems 102. When the unattended physiological data is obtained continuously or frequently, a trending algorithm (e.g., average, median, peak-finding, etc.) is applied, in one embodiment, to break the stream of physiological data into discrete blocks of unattended physiological data. For example, a continuous stream of unattended physiological data can be separated into blocks of a predetermined duration and a trending algorithm can be applied to each block. Further, when a network event is received, the patient monitoring systems 102 can decide if requested measurements are already available or if a new measurement need to be acquired.
One or more sensors 112 suitably obtain the unattended physiological data. However, it is also contemplated that the physiological data is obtained from other components of the IT infrastructure 100, such as lab equipment, components with user input devices, and so on. The sensors 112 measure physiological parameters of the patients and generate physiological data indicative thereof. In certain embodiments, the sensors 112 include one or more electrocardiographic (ECG) electrodes, blood pressure sensors, SpO2 sensors, pulse sensors, thermometers, respiratory sensors, exhaled gas sensors, noninvasive blood pressure (NBP) sensors, and the like. Typically, the sensors 112 are disposed on the person of a patient and external to the patient monitoring systems 102. However, sensors local to the patient monitoring systems are contemplated. Where the sensors 112 are external, the physiological data can be obtained via a databus, such as a serial bus, a universal serial bus (USB), or the like; a body coupled network; a Bluetooth, a ZigBee, a wired or a wireless network; a medical body area network (MBAN); or the like.
One challenge with unattended physiological data is that it may be unreliable. Measurements can become skewed and/or distorted by movement artifacts and/or from not knowing under what condition the measurements were obtained. To address this problem, in certain embodiments, the patient monitoring systems 102 take one or more actions to ensure unattended physiological data accurately reflects the physiological state of the patients. The actions can include requesting manual confirmation of measurements from clinicians via one or more displays 114 and/or one or more user input devices 116 of the patient monitoring systems 102. Additionally or alternatively, the actions can include obtaining additional data, such as data pertaining to motion, patient activity, body posture, and so on, to allow determination of the state of the patients for which unattended physiological data relates. For example, data indicating whether a patient is in motion (e.g., climbing stairs) can be obtained from an accelerometer incorporated in one or more of the sensors 112. When the additional data indicates the measurements of the unattended physiological data are likely to be skewed and/or distorted, the obtained unattended physiological data can be discarded as not representative of the normal physiological state of the patient.
In certain embodiments, the patient monitoring systems 102 further obtain baseline data for patients cared for by the medical institution. Baseline data includes attended physiological data and patient scores, such as an early warning score (EWS) or a modified early warning score (MEWS), and is typically obtained during ward rounds of a clinician. Attended physiological data is obtained with the supervision of a clinician and is indicative of measurements of physiological parameters (or vital signs) of the patients, such as heart rate, respiratory rate, and the like. Attended physiological data is typically obtained wholly or partially from the user input devices 116. However, it is contemplated that the attended physiological data is received by other means. For example, the attended physiological data can be obtained from the sensors 112, provided a clinician ensures the patient does not taint the physiological data. Since attended physiological data is collected with clinician supervision and/or input, attended physiological data can further include manual assessments of physiological parameters of the patient, such as level of consciousness, concern, pain, urine output, and other data pertaining to physiological parameters that cannot be measured by one of the sensors, and/or manual measurements of physiological parameters, such as temperature, respiration rate, and so on.
A patient score assesses the current status of the patient (or, in extreme conditions, the risk of death of a patient) and is obtained through calculation using the attended physiological data and a scoring table of physiological parameters. Suitably, the attended physiological data includes measurements for each physiological parameter of the scoring table. However, attended physiological data including fewer than all of the physiological parameters of the scoring table are contemplated. Scoring tables are completely user configurable, and no assumption regarding the used parameters and scoring thresholds are made. In certain embodiments, the patient monitoring systems 102 facilitate the generation of a patient score. For example, it is contemplated that a process in a processor-based controller 120 of the patient monitoring systems 102 automatically calculates a patient score based on obtained attended physiological data and a scoring table. As another example, it is contemplated that the patient monitoring systems 102 merely provide a clinician with the scoring table and/or the attended physiological data, thereby leaving it to the clinician to calculate the patient score and input it into the relevant patient monitoring system via the user input devices 116.
The scoring table is suitably obtained from a remote component of the IT infrastructure 100, such as the patient information system 104, the patient information display systems 106, or the deterioration detection system 108, via the communications network 110. In such embodiments, a graphical user interface displayed on the remote component can be employed to facilitate selection and/or definition of the scoring table. However, it also is contemplated the scoring table is obtained from one or more memories 118 of the patient monitoring systems 102 and/or selected and/or defined by a clinician via the user input devices 116. As to selection and/or definition, a graphical user interface on the displays 114 of the patient monitoring systems 102 can be employed to facilitate selection and/or definition of the scoring table. Regardless of where the scoring table is obtained from, the scoring table is suitably selected and/or defined individually for each patient based on attributes of the patient, such as illness and/or history.
With reference to
Referring back to
In certain embodiments, the patient monitoring systems 102, in addition to relaying baseline data and/or unattended physiological data, monitor the patients based on the received baseline data and/or unattended physiological data and/or update associated displays to graphically present the baseline data and/or unattended physiological data to clinicians. As to the former, when baseline data and/or unattended physiological data indicates a patient needs medical attention due to, for example, increasing and/or decreasing respiration rate or blood pressure, the patient monitoring systems 102 that received the baseline data and/or unattended physiological data typically generates audio and/or visuals alerts and/or messages notifying clinicians thereof. It is contemplated that message can be provided to the clinicians via the communications network 110.
To carry out the above noted functionality, the patient monitoring systems 102 suitably include the memories 118 and one or more processor-based controllers 120. In certain embodiments, it is contemplated that the patient monitoring systems 102 include patient worn monitors and/or beside monitors. The memories 118 store executable instructions for performing one or more of the above noted functions of the patient monitoring systems 102. Further, in certain embodiments, the memories 118 act as a buffer for the physiological data before it is relayed to the patient information system 104 or some other component of the IT infrastructure 100. This is advantageous when, for example, the patient monitoring systems 102 are not connected to the communications network 110 all the time. The physiological data can be buffered and relayed when a connection to the communications network 110 becomes available. The processor-based controllers 120 execute the executable instructions stored on the memories 118 to carry out the functions associated with the patient monitoring systems 102. Where the patient monitoring systems 102 are operative to relay physiological data over the communications network 110, the patient monitoring systems 102 further include one or more communications units 122 facilitating communication between the processor-based controllers 120 and the communications network 110.
The patient information system 104, such as a central record medical database, receives baseline data and/or unattended physiological data for the patients and stores the data in one of one or more memories 124 thereof. Typically, the data is received from components of the IT infrastructure 100, such as the patient monitoring systems 102 and/or the patient information display systems 106, via the communications network 110. However, it is also contemplated that the data is received via one or more user input devices 126 of the patient information system 104. To facilitate receipt of such data, the patient information system 104 can include a display 128 presenting a user with a graphical user interface. In certain embodiments, the patient information system 104 further displays and/or allows manipulation of the baseline data and/or unattended physiological data in the memories 124 using the user input devices 126 and/or the display 128. Additionally or alternatively, in certain embodiments, the patient information system 104 further allows components of the IT infrastructure 100 to access the data in the memories 124 via the communications network 110.
To carry out the above noted functionality, the patient information system 104 suitably includes the memories 124 and one or more processor-based controllers 130. In certain embodiments, it is contemplated that the memories 124 and the processor-based controllers 130 define one or more computer servers. The memories 124 store executable instructions for performing one or more of the above noted functions of the patient information system 104. Further, as noted above, the memories 124 store baseline data and/or unattended physiological data. The processor-based controllers 130 execute the executable instructions stored on the memories 124 to carry out the functions associated with the patient information system 104. Where the patient information system 104 is operative to receive physiological data from the communications network 110, the patient information system 104 further includes one or more communications units 132 facilitating communication between the processor-based controllers 130 and the communications network 110.
The patient information display systems 106 receive baseline data and/or unattended physiological data for the patients cared for by the medical institution over the communications network 110 from a component of the IT infrastructure 100, such as the patient monitoring systems 102 and/or the patient information system 104. Typically, each of the patient information display systems 106 receives baseline data and/or unattended physiological data for a plurality of patients, but a patient information display system that receives baseline and/or unattended physiological data for a single patient is contemplated. Using the received data, the patient information display systems 106 monitor the patients and/or update associated displays 134 to graphically present the data to clinicians. As to the former, when data indicates a patient needs medical attention due to, for example, increasing and/or decreasing respiration rate or blood pressure, the patient information display systems 106 that received the data typically generates audio and/or visuals alerts and/or messages notifying clinicians.
In certain embodiments, the patient information display systems 106 further allow clinicians to input baseline data via one or more user input devices 136. It is contemplated that graphical user interfaces presented on the displays 134 can be employed to make it easier for the clinicians to enter the data. Upon inputting baseline data, the baseline data is suitably relayed to the patient information system 104 and/or other components of the IT infrastructure 100, such as the deterioration detection system 108, via the communications network 110. Additionally or alternatively, in certain embodiments, the patient information display systems 106 include one or more of nursing stations, bedside monitors, mobile patient information displays, a central monitoring station, a PDA, a tablet computer, a pager, and the like.
To carry out the above noted functionality, the patient information display systems 106 suitably include one or more communications units 138, one or more memories 140, and one or more processor-based controllers 142. The communications units 138 facilitate communication between the processor-based controllers 142 and the communications network 110. The memories 140 store executable instructions for controlling a processor of the processor-based controllers 142 to perform one or more of the above noted functions of the patient information display systems 106. Further, in certain embodiments, the memories 140 act as a buffer for the baseline data before it is relayed to the patient information system 104 or some other component of the IT infrastructure 100. The processor-based controllers 142 execute the executable instructions stored on the memories 140 to carry out the functions associated with the patient information display systems 106.
The deterioration detection system 108 obtains baseline data for the patients from components of the IT infrastructure 100, such as the patient information system 104 and/or the patient monitoring systems 102, and/or one or more user input devices 144 of the deterioration detection system 108, and tracks the most recent baseline data for each of the patients. The baseline data is typically obtained when clinicians make ward rounds and need not be received at predefined intervals. In that regard, the baseline data can be obtained asynchronously. Further, the baseline data suitably represents a complete assessment of the patient for which it relates. In other words, attended physiological data of baseline data suitably includes measurements for each of the physiological parameters employed by the scoring table used to generate the patient score of the baseline data. In certain embodiments, where the age of the most recent baseline data exceeds a predetermined amount, the deterioration detection system 108, for example, generates an audio and/or visual alert and/or sends a message to, for example, a clinician, via the communications network 110 and a pager, PDA, laptop or tablet computer, or the like.
In certain embodiments, upon obtaining baseline data, it is compared against previously obtained baseline data to detect deterioration. It is contemplated that this can be performed through comparison of the patient scores or through comparison of individual physiological parameters, as described below. Additionally or alternatively, in certain embodiments, a plurality of retrospective baseline data is obtained at the same time. For example, the patient monitoring systems 102 buffered the retrospective baseline data until a connection to the communications network 110 was available. In such embodiments, the baseline data can be compared to detect deterioration. Insofar as deterioration is detected, varying actions can be taken based upon the degree of difference between the scores. Actions include one or more of generating an audio and/or visual alert of patient deterioration, logging the deterioration in a database, sending a message and/or page to a clinician via, for example, the communications network 110, and so on.
With reference to
Referring back to
Although the unattended physiological data is typically obtained intermittently and/or continuously, in certain embodiments, the unattended physiological data is retrospective and/or obtained asynchronously. For example, the patient monitoring systems 102 can buffer the physiological data until a connection to the communications network 110 is available. Where the unattended physiological data is retrospective, typically only the most recent measurements are considered and/or a trending algorithm (e.g., average, maximum, etc.) is applied to the physiological data. However, it is also contemplated that, retrospective data can also be employed to detect patient deterioration in the past in the same manner discussed below. In such embodiments, each retrospective unattended physiological data received is compared against the most recent retrospective baseline data temporally preceding it.
With reference to
Referring back to
In certain embodiments, before action is taken, the deterioration detection system 108 seeks reassurance that the unattended physiological values are not skewed and/or distorted by movement artifacts and/or from not knowing under which condition the measurements were done. When the unattended physiological data is obtained continuously, measurements can be captured at a predetermined interval for a predetermined number of times. When the unattended physiological data is not obtained continuously, the deterioration detection system can request the patient monitoring systems 102 to repeat measurements at a predetermined interval or timely repetition patterns and/or sequences for a predetermined number of times. To request the patient monitoring systems 102 to repeat measurements, the deterioration detection system 108 can send a network event to the patient monitoring systems 102 requesting unattended physiological data as to one of the deteriorated measurement, a subset of all measurements, all measurements, or the like. Upon capturing or obtaining the measurements, they can be employed to determine whether a patient was in an intermittent state or if the measurements were representative for the patient.
The amount of time and the number of repetitions is adapted to the individual environment, including the kinds of measurement, as well as level of care and general patient class. Further, the amount of time and the number of repetitions is suitably obtained from a clinician. In that regard, the user input devices 144 of the deterioration detection system 108 can be employed to capture these parameters from the clinician. In certain embodiments, a graphical user interface of the deterioration detection system 108 can be presented to a clinician via a display 146 to facilitate such a task. Alternatively, other components of the IT infrastructure 100 can be employed to obtained the amount of time and the number repetitions from the clinician. While the amount of time and the number of repetitions are suitably obtained from the clinician, automated approaches to defining these parameters are contemplated. For example, algorithms based on one or more of the scoring table; actual score or sub-scores; severity of deterioration; additional available (e.g., automatically captured) status information of the patient, such as current patient activity, activity trend, and posture; and so on, can be employed to automatically define the parameters.
With reference to
To carry out the above noted functionality, the deterioration detection system 108 suitably includes a communication unit 148, a memory 150, and a processor-based controller 152. The communications unit 148 facilitates communication between the processor-based controller 152 and the communications network 110. The memory 150 stores executable instructions for controlling the processor of the processor-based controller 152 to perform one or more of the above noted functions of the patient deterioration system 108. The processor-based controller 152 executes the executable instructions stored on the memory 150 to carry out the functions associated with the patient deterioration system 108. In certain embodiments, the patient deterioration system 108 further includes the user input devices 144 and/or the display 146 allowing a clinician to manually enter baseline data and/or other parameters employed by the deterioration detection system 108.
While the deterioration detection system 108 is shown as a separate component of the IT infrastructure 100, it is to be appreciated that it can be integrated with other components of the IT infrastructure 100. For example, the deterioration detection system 108 can be integrated with the patient information system 104. As another example, the deterioration detection system 108 can be integrated with one or more of the patient monitoring systems 102.
With reference to
After identification 602 of the scoring table for a patient, baseline data is generated 604 intermittently for the patient by a clinician. Baseline data includes attended physiological data and a patient score. The attended physiological data includes data indicative of manually or automatically collected measurements of physiological parameters of the patient and, optionally, data indicative of manual assessments of physiological parameters of the patient. The patient score is generated automatically or manually from the scoring table using the attended physiological data.
Unattended physiological data is also collected 606 for a patient. Unattended physiological data includes data indicative of measurements of at least one of the physiological parameters of the scoring table for the patient. Typically, however, unattended physiological data includes a subset of the physiological parameters. Unattended physiological data is collected automatically by, for example, a patient worn device or bed side device. Further, unattended physiological data is typically collected continuously, on-demand, or upon the occurrence of an event, such as a timer event. Where the unattended physiological data is continuously collected, the unattended physiological data can be broken into discrete blocks based on time and trending algorithms can be applied to the discrete blocks.
When new unattended physiological data is collected 606 for a patient, the unattended physiological data is compared 608 against the most recent baseline data for the patient using the scoring table to detect deterioration. Insofar as no deterioration is detected, the method 600 is suspended until further unattended physiological data is collected. Insofar as deterioration is detected, however, the method 600 suitably seeks re-assurance 610 of the unattended physiological data.
Re-assurance 610 checks that the measurements of a patient are really deteriorated and that the patient is in a baseline physiological state. If the patient is not in a baseline physiological state, the measurements may be tainted. In certain embodiments, re-assurance 610 includes triggering additional measurements of at least one of the physiological parameters of the unattended physiological parameters. Suitably, the at least one includes the deteriorated physiological parameters. Additionally or alternatively, in certain embodiments, re-assurance 610 includes capturing measurements at a predetermined interval for a predetermined number of times from a continuous stream of unattended physiological data.
If a patient's condition has deteriorated and, if appropriate, the deterioration has been reassured, a clinician is notified 612 of the deterioration. Suitably, such notification prompts the clinician to take further action 614, such as generating additional baseline data.
With reference to
In certain embodiments, actions are taken to verify that the measurements of the physiological data are representative for the patient. Typically, this is only when the physiological data includes unattended physiological data. For example, verification of the measurements of the physiological data is received from a clinician. As another example, in response to measurements which differ by more than a threshold from earlier measurements, the deterioration detection system 108 controls or otherwise causes one of the patient monitoring systems 102 to retake the measurements in question. As yet another example, additional data, such as data pertaining to motion, patient activity, body posture, and so on, is received from a component of the IT infrastructure 100, such as one of the patient monitoring systems 102. Thereafter, a determination as to whether the physiological data accurately reflects the physiological state of the patient is made based on the additional data. The physiological data is discarded in response to the physiological data not accurately reflecting a baseline physiological state of the patient and taken again.
Additionally or alternatively, in certain embodiments, the physiological data is continuously received. As above, this is typically only when the physiological data includes unattended physiological data. In some of these embodiments, the physiological data is divided 708 into discrete blocks of physiological data based on time. Thereafter, a trending algorithm is applied 710 to each of the discrete blocks, so each of the blocks is associated with a single measurement for each of one or more physiological parameters. Trending algorithms include, for example, average, median, peak-finding, etc.
Upon receiving 706 the physiological data, the measurements of the physiological data are compared 712 to corresponding measurements in most recent attended physiological data using the scoring table to determine any change in the patient score. In certain embodiments, in response to a physiological parameter of the physiological data deteriorating as compared to a corresponding physiological parameter in the most recent attended physiological data, deterioration is verified 714. For example, one of the patient monitoring systems 102 is controlled (via, for example, a network event) to take measurements of at least one of the physiological parameters a predetermined number of times in one or more predetermined intervals or timely repetition patterns and/or sequences. These additional measurements are then used to determine whether the detected deterioration is representative of the patient. A clinician is notified 716 of patient deterioration in response to a physiological parameter of the physiological data deteriorating as compared to a corresponding physiological parameter in the most recent attended physiological data.
With reference to
As used herein, a memory includes one or more of a non-transient computer readable medium; a magnetic disk or other magnetic storage medium; an optical disk or other optical storage medium; a random access memory (RAM), read-only memory (ROM), or other electronic memory device or chip or set of operatively interconnected chips; an Internet/Intranet server from which the stored instructions may be retrieved via the Internet/Intranet or a local area network; or so forth. Further, as used herein, a processor-based controller includes one or more of a microprocessor, a microcontroller, a graphic processing unit (GPU), an application-specific integrated circuit (ASIC), a field-programmable gate array (FPGA), and the like; a user input device includes one or more of a mouse, a keyboard, a touch screen display, one or more buttons, one or more switches, one or more toggles, and the like; and a display includes one or more of a LCD display, an LED display, a plasma display, a projection display, a touch screen display, and the like.
The invention has been described with reference to the preferred embodiments. Modifications and alterations may occur to others upon reading and understanding the preceding detailed description. It is intended that the invention be constructed as including all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/IB2012/050796 | 2/22/2012 | WO | 00 | 8/27/2013 |
| Number | Date | Country | |
|---|---|---|---|
| 61447836 | Mar 2011 | US |
