The present invention relates to information acquisition from, and control of, remotely located scanners, and use of such scanners for collection of news, traffic (e.g., traffic incident reporting), weather, police, fire and rescue activities, and the like.
Information gathering organizations are always looking for methods to improve the information gathering process. Technology has provided many new tools and opportunities for such organizations. The ability to monitor public airwaves has provided a valuable tool to alert and inform an organization of possible incidents and events. As technology progressed, Radio Spectrum Frequency scanners became a basic tool to collect information. A scanner or scanning radio is a specialized radio receiver designed to tune a wide range of frequencies. Frequencies are stored in channels and selectively scanned or the scanner can search through an entire frequency range. Scanner receivers differ in contrast to radio communication receivers in that they usually do not have a variable frequency oscillator (VFO) and they usually do not cover the high frequency (HF) 3-30 MHz spectrum. Scanners usually scan and search much faster than regular receivers.
Scanners allow a user to obtain information from organizations such as Police, Fire-Rescue and Ambulance. Dispatching activities can inform a listener of possible issues that affect a community and impact activity, such as travel. One problem that occurs when trying to monitor radio broadcast activities is the limited distance that these broadcast signals cover. Signals are shared and transmission power is limited to avoid problems with the shared signals. To extend the reach of an information gathering organization, satellite collection agents were employed to gather information not physically present at a primary gathering office.
More advanced applications of radio frequency spectrum scanners placed a scanner into a remote location and used audio links to forward sound to a central monitoring facility. This solution provided a blind solution making it difficult to attribute the sound of a transmission to the transmitting entity. Being able to see a scanner display allows a user to cover many frequencies and view the frequency when a transmission is heard, thereby associating the transmission source. In addition to the difficulty with the blind nature of a remote audio solution, any tuning or changes that were required to the remote unit required someone to physically visit the unit in the field. Real-time interaction is extremely valuable, but not available to any of these legacy solutions. If an important transmission is heard, locking into a frequency allows a user to acquire addition information that may be lost if scanning resumes. Scanning of frequency banks is likely to occur when control is not present.
Integration of audio, video and control are desirable to maximize the value of a remotely deployed unit. Some existing products provide a limited ability to meet this need. For example, products are available which allow a scanner to be controlled by a personal computer (PC) located physically adjacent to the scanner and connected to an RS-232C port of the scanner via a hardwired cable (PC interface). Software executing on the PC presents a simulated display of the scanner and the user can control selected functions of the scanner by interacting with the simulated scanner display. One such product is software associated with the Model No. IC-PCR100 and PCR1000 scanners from Icom Inc., Osaka, Japan. Another product is third-party software for the Model Bearcat BC780XLT Trunk Tracker III scanner from Uniden, Fort Worth, Tex. The third-party software is WinScan® 780, Version 1.0 Scanner Control Software, available from Pozilla Software Corp. Neither of these products, nor the associated software, allow for remote user capabilities. When using these PC interface products, the external speaker output jack of the scanner is connected to a speaker or microphone input of the PC, thereby allowing the scanner's audio to be played in real-time through the speakers of the PC. This scheme provides no ability to play the audio at a location remote from the PC.
Many software and hardware manufacturers produce audio and streaming products. Microsoft produces Windows Media, and RealNetworks, Inc., Seattle, Wash., produces a plurality of streaming audio products. The current methods of streaming audio suffer from buffering and time delays, as discussed in more detail below. Hardwired audio links have also been employed to provide blind solutions.
Referring to
Streaming audio, especially in real-time, is constrained by parameters associated to streaming technology. Streaming data operates most efficiently on low overhead protocols, which reduces head end resources and network bandwidth requirements. Common distribution protocol leverages User Datagram Protocol (UDP), Multicast, or other broadcast technologies to deliver data over a stateless and connectionless network transport. The combination of real-time encoding, broadcasting to many users, and connectionless or lightweight data delivery has several adverse effects on an audio or video stream.
Buffering of streaming audio is problematic when applied to certain applications that have real-time needs. An audio stream is buffered to maximize compression. Compression is more effective when applied to larger data sets. To achieve compression, the encoding source buffers data to achieve better compression. The client or listener also buffers a data stream. Client buffering addresses network delivery issues such as out of sequence packets and network throughput issues. While buffering provides an enhanced experience for the average Internet user, buffering introduces a serious problem for a control-based system. Buffering delays transmission, which introduces a delay in the control feedback loop. For example, audio systems such as RealAudio® (a product of RealNetworks, Inc., Seattle, Wash.) use a buffering system to give the illusion of real-time transfer. The software in such audio systems delay reproducing a transmission for a human perceptible period of time in the order of seconds to build a buffer of data. This process ensures that a smooth reproduction will occur even if there is a delay in the transmission link.
The only conventional way to coordinate audio, video and control of a scanner in real time is to have personnel local to the scanner itself. In addition, scanning radio broadcasts covering large number of public agencies requires several difference technologies, including legacy analog systems, trunk systems and new digital transmission methods. The majority of the scanner market is focused on non-commercial applications such as the hobbyist. Thus, there is a significant problem in developing real-time remote control scanner solutions that work across such various platforms. In sum, prior approaches and technologies continue to have deficiencies, especially in processing information that requires real-time control and other remote interaction, as well as real-time listening of audio.
In a first embodiment of the present invention, a processing unit receives an audio signal output of the scanner. The processing unit prepares the audio signal for transmission over a network by encoding the audio signal output of the scanner to digitally encoded audio. A scanner workstation is physically remote from the processing unit and the scanner. The workstation includes an application for receiving the digitally encoded audio and decoding the digitally encoded audio to an original audio signal output of the scanner. A transport network having at least two edge nodes is in communication at one edge node with the processing unit to receive the digitally encoded audio and is in communication at the other edge node to provide the digitally encoded audio to the scanner workstation.
In a second embodiment of the present invention, traffic report information is produced using one or more scanners. Each scanner includes an audio signal output. A processing unit receives an audio signal output of the scanner. The processing unit prepares the audio signal output for transmission over a network by encoding the audio signal output to digitally encoded audio. The audio signal output includes events that affect traffic. A scanner workstation is located physically remote from the processing unit and the scanner. The workstation includes an application for receiving the digitally encoded audio and decoding the digitally encoded audio to an original audio signal output of the scanner. A transport network having at least two edge nodes is in communication at one edge node to the processing unit to receive the digitally encoded audio and is in communication at the other edge node to provide the digitally encoded audio to the scanner workstation. A human agent receives the original audio signal outputs of the one or more scanners provided by the scanner workstation and converts the original audio signal outputs of traffic incidents into traffic report information.
In the first and second embodiments, the audio signal output of the scanner is delivered via a voice over IP process to the workstation in real-time, or in near real-time without human -perceptible delays associated with buffering.
In a third embodiment of the present invention, selected functions of a scanner are controllable from a remotely located site in real time. A processing unit is in communication with the input/output remote control port of a scanner. The processing unit includes a digital interface associated with the scanner and a remote control and video encoding application. A scanner control workstation is provided in a location physically remote from the processing unit and the scanner. The workstation includes a remote control and video decoding application. A transport network having at least two edge nodes is in communication at one edge node to the processing unit and is in communication at the other edge node to the scanner control workstation. The transport network, digital interface and remote control and video encoding and decoding applications allow the workstation to control and visually monitor selected functions and settings of a scanner in real time and to enter commands to selectively control functions and settings of the scanner in real time.
In all of the embodiments described above, the transport network may be a public or private network, or may be a switched network.
The foregoing summary, as well as the following detailed description of preferred embodiments of the invention, will be better understood when read in conjunction with the appended drawings. For the purpose of illustrating the invention, there is shown in the drawings embodiments which are presently preferred. It should be understood, however, that the invention is not limited to the precise arrangements and instrumentalities shown.
In the drawings:
Certain terminology is used herein for convenience only and is not to be taken as a limitation on the present invention. In the drawings, the same reference letters are employed for designating the same elements throughout the several figures.
The present invention is described in the context of a Remote Radio Spectrum Information Acquisition System (hereafter, “scanner system”) which provides real-time remote acquisition of a scanner's audio signals and visual display, and real-time remote control of scanner operations (e.g., settings and functions). More specifically, the attributes of the scanner system include:
One use of the scanner system is to gather information in a regional market by listening to geographically distant broadcasts available on radio spectrum frequencies. By synchronizing multi-spectrum monitoring, audio delivery, visual cueing, and control of spectrum reception, geographically independent persons can process scanner information as if they were physically present in the market. Thus, operators can gather information from public agencies and radio broadcasts from a remote market as if they were present in the market. The scanner system allows an operator full control of spectrum receivers and provides audio synchronized with visual information in real-time with control of scanning devices.
The real-time audio capabilities can also be characterized as being near real-time without human-perceptible delays associated with buffering used in streaming audio schemes.
High-level overviews and conceptual drawings (
A scanner system is described herein, which expands the realm of the information gathering process to support geographically distant sources including interaction capabilities required to extend and enhance the acquisition of information from a remote location. Details descriptions cover reference implementations to further define the remote information gather system. Optional extensions and optional configurations are described to qualify the additional capabilities of the scanner system. As an introduction, high level concepts and architecture are provided to orient further descriptions.
Information is available from many sources as a transmitted signal in the radio spectrum. These broadcasts conform to local radio spectrum legislative requirements, which allocate frequencies, transmission modes and transmission power. As a result, many information sources are only available for reception within a limited distance from a transmitter. For example, public agencies such as Fire-Rescue and Police use radio spectrum broadcast systems to communicate information. Due to signal sharing requirements, availability of a given signal is present in a limited physical area. Many such signals exist and offer a wealth of publicly available information. A remote information gathering system offers the capability to process the large amount of information, which are not physically present to a user many miles away.
The Remote Radio Information Acquisition System is composed of several physical components. In addition, the physical location of these components is of vital importance to the operations of the system.
The scanner system is comprised of three major components.
Scanner System Embodiment
Applications of the concepts outlined for the scanner system have several possible incarnations. One embodiment of the scanner system is optionally implemented with custom software optimized for specific tasks. Another embodiment is implemented with general-purpose software packages, which supply required aspects of the target functionality. Functional aspects of the system remain the same in either implementation. General-purpose software packages provide required functionality, while custom software implementations optimize target functionality. Implementations of the scanner system described herein leverage several general-purpose software packages configured and integrated with other scanner system components.
Software on the Radio Spectrum Receive Site (704 through 711) provides the audio encoding (708) of the Radio Spectrum Processor, Video Encoding (709) and Control agents (707). Audio Encoders (705) leverage sounds system hardware found on PC's. Standard audio and streaming software will not support the requirements of the scanner system. Audio software must perform in real-time without buffering found in standard streaming audio (705 and 708) software. One preferred embodiment of the scanner system leverages conventional Phone to PC audio software (705 and 708). Several audio encoding systems are available to facilitate the real-time audio link required by the scanner system. Off-the-shelf audio encoding software commercially available from BuddyPhone (BuddyPhone Inc., San Diego, Calif.), Net2Phone® (Net2Phone Inc., Newark, N.J.), and PC2Phone (software available from iConnectHere, a consumer division of deltathree, inc., New York) support appropriate PC-to-PC Audio Links. One particularly preferred embodiment, described in more detail in
Table 1 defines an example message format to interact with Radio Spectrum Processor (703). All externally visible or accessible Control Agents (710) provide security through authentication and entitlements controls. One embodiment of the scanner system leverages operating system users and passwords, but the scanner system is not limited to this approach.
The Radio Spectrum Receive Site runs software to facilitate registration of dynamic network addresses (515) when the transport services are deployed on a non-deterministic address. Network addresses assigned by Transport Network Service (712) providers can be dynamic, similar to Dynamic Host Control on a local LAN. In this configuration, the Processor Unit (704) at the Radio Spectrum Receive Site uses a registration service to associate the currently assigned IP address to a Domain Name Services (DNS) name. Service providers such as Dynamic DNS Network Services LLC. or The Art of DNS are examples of Internet-based services that provide Domain Name Service for non-deterministic or dynamically assigned IP addresses. Using a well-defined name, the Data Delivery Control Unit can find the network location of a unit even if the network address is floating or changing.
Transport Network Services (link facilitating 712 to 801) are implemented in any one of the following ways. Transport services options include, but are not limited to, private or public network connections as well as the Internet. Network connections support both hardwired (
Switched Network Services using POTS lines or ISDN lines provide low bandwidth connections. The scanner system adjusts automatically to the bandwidth available. Manual configuration of Audio Encoding (705) levels of 8 bit or 4 bit levels enhance performance on marginal network connections. Many switched Transport Networks and some hardwired Transport Networks services operate with Dynamic IP address allocation. The Data Acquisition Control Unit (601) is configured to publish an IP address to a DNS name. Dynamic Registration implements the requirement for non-deterministic IP addressing.
Operation of the scanner system provides a tightly coupled interaction required to process the large amounts of information disseminated over the radio broadcast systems.
Using visual feedback, a User invokes controls to adjust the Radio Spectrum Processor or Processor Unit. Visual feedback loop is also leveraged as a secondary information source. Administration and technician activities are examples of events requiring control, which are driven by visual feedback. Table 3—Visual Events and Interaction, provides a non-exhaustive list of examples of events and controls leveraging video data.
One preferred use of the scanner system is for a user to monitor a remotely located scanner or bank of scanners for events that affect traffic and to convert the events into traffic report information for creation of traffic reports. If an important transmission is heard relating to an event that affects traffic, the operator at the workstation can use the remote control application software to lock into the current frequency of the scanner and acquire additional information regarding the event that may be subsequently transmitted and picked up by the scanner on the current frequency.
The present invention may be implemented with any combination of hardware and software. If implemented as a computer-implemented apparatus, the present invention is implemented using means for performing all of the steps and functions described above.
The present invention may be implemented with any combination of hardware and software. The present invention can be included in an article of manufacture (e.g., one or more computer program products) having, for instance, computer useable media. The media has embodied therein, for instance, computer readable program code means for providing and facilitating the mechanisms of the present invention. The article of manufacture can be included as part of a computer system or sold separately.
It will be appreciated by those skilled in the art that changes could be made to the embodiments described above without departing from the broad inventive concept thereof. It is understood, therefore, that this invention is not limited to the particular embodiments disclosed, but it is intended to cover modifications within the spirit and scope of the present invention.
This application is a divisional of U.S. application Ser. No. 10/463,056, now U.S. Pat. No. 7,406,543, filed Jun. 17, 2003, the entire disclosure of which is incorporated herein by reference. This application claims the benefit of U.S. Provisional Application No. 60/430,021 filed Nov. 29, 2002 entitled “REMOTE RADIO SPECTRUM INFORMATION ACQUISITION.”
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20090024738 A1 | Jan 2009 | US |
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Parent | 10463056 | Jun 2003 | US |
Child | 12180295 | US |