1. Field of the Invention
The present general inventive concept most directly relates to conducting interviews using a compact portable video recording device. More specifically, the inventive concept relates to providing portable recording capabilities; and real-time external streaming over a wireless network. The video recording devices perform in a variety of conditions while maintaining functionality as well as maintaining a continued high level of quality, as well as being durable, portable and maintained in a simple in a compact form. The data recorded is verified and authenticated for user validation and integrity measurements.
2. Description of the Related Art
Interviews are traditionally conducted in offices and with today's progressive and changing society sometimes interviews are conducted at local coffee shops, in a local park, by criminal justice and defense individuals in the field, child services employees visiting a family home or even by an individual in the comfort of their own home, just to name a few. When interviews conducted inside and outside of the office, the notes of the interviewer are relied on to relay the information acquired during the interview. Many times these notes are then shared in order to brief others on the interview that was conducted. Capturing the interviews on video recording device alleviates the need to relying on second hand notes. Notes do not capture behavior, emotions, and sounds occurring during the interview. The need for portability has changed the market. The ability to conduct an interview from anywhere is the ideal situation. In order to accomplish this, the interviewing device must be portable, adjustable, efficient, high quality picture and sound, maintain integrity of the recordings, and provide a diverse method for displaying and accessing the data. There are numerous opportunities for use of such a compact portable video recording device in today's growing market.
Continuing advances in video recording devices, coupled with steady progress in the current demand to be less restrictive and more mobile over the past several decades, has necessitated that considerable engineering resources be devoted to improving the picture and sound quality while maintaining a convenient, compact, easy to use structure for the video recording device. The concept of creating a video recording device is generally utilized for example, mobile telephones use wireless communication and cameras. However, wireless use in the mobile phones consumes large amounts of power and power depletes quickly without recharging. This results in a battery with a fairly rapid power depletion and a video recording device with limited functionality. The constant and swift battery drain creates the need for a device with the ability to utilize the benefit wireless technology while minimizing the burden of the excessive power consumption. Balancing power consumption with allowing the portable video recording device to be compact and easily movable, is very important.
Within the portable video recording device field many cameras use a continuous recording loop of local storage to compensate for any temporary loss of network communications that might occur. This type storage does not preserve the data recording in its entirety and does not allow for an efficient mechanism for creating a reliable and storable recording. Some systems record on hard disk drives and have external cameras. This type of system is quite bulky and the use of these types of systems limit portability. In order to minimize the loss of data due to system crashes or network data loss, creating reliable storage is essential developing a dependable device. Not only must the storage be reliable, it must also be provided in a format that allows for interchangeable use, between different users, devices, and other computer readable mediums.
Many audio/visual recording devices use proxy servers that allow communication with other devices and authenticate devices for the purposes of video streaming and conferencing. The use of a proxy server can act as caching server allowing data to load faster and can mask IP addresses for anonymity; however, a proxy server use can leave the user and the video recording device open to many other vulnerabilities. A proxy server can easily be compromised and when compromised, all data is subject to theft and system integrity is degraded. This creates a need to enable secure access to a network without the use of proxy server.
There are several purposes for which the recorded data can be used, of which can include, but are not limited to evidentiary, security, confirmation, and validation, purposes. Data authentication becomes a pivotal concern. The ability to authenticate data enhances not only the value of the recorded data but also the diversification of the data use. In many existing systems, the use of captured audio/visual video device data requires the entire camera for authentication. This creates a burdensome hardship for the user, not only is the camera no longer available for use while the data is being authenticated, it is also very inconvenient and an ineffective use of resources.
Thus, there is a need in the art for a system to improve the mobility of the interviewing process. This is accomplished by the development of a system for a portable video recording device that is compact, portability, high quality audio and recordings, provides authenticated recordings, uses access point base communication; is conscientious of power consumption by minimizing power loss, accommodates for dependable storage and secures and maintains integrity of recorded data.
The present general inventive concept provides for conducting interviews using a compact portable video recording device. More specifically, the inventive concept relates to providing portable recording capabilities; and real-time external streaming over a wireless network. The video recording devices perform in a variety of conditions while maintaining functionality as well as maintaining a continued high level of quality, as well as being durable, portable and maintained in a simple in a compact form. The data recorded is verified and authenticated for user validation and integrity measurements.
Additional aspects and utilities of the present general inventive concept will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the general inventive concept.
The foregoing and/or other aspects and utilities of the present general inventive concept may be achieved by providing a device for a compact portable video recording device that unfolds to activate and record. The portable, pocket sized video recording device lies flat on any tabletop or surface area. The lower foundational support is weighted and is connected to a variable hinge. The variable hinge allows the portable video recording device to quickly aim and be positioned to accommodate a fluid motion for setting up the device. Upon activation of the device by unfolding, the local wireless network communication is activated and a recording can be automatically or manually activated.
The portable video recording device includes a casing module. Some of the features included in the casing module includes the camera, microphones, operational indicators functions, fill lights, microprocessors, memory, magnet switches, sensors, memory card readers, foregoing is not an exhaustive list, only a summary of the features. The casing module contains an imbedded camera that is connected to a weighted foundational support by means of a variable hinge which can be adjusted in an upward or downward position to adjust the viewing angle. The variable hinge allows the casing module to be aimed in any direction and maintain its position. The adjusting of the variable hinge creates an elevation angle which can be directed at different degrees to capture the user preferred image for the video data recording. The variable hinge elevation angle can be adjusted, aimed and positioned on any angle elevation up to the point where the casing module is in contact with the lower foundational support. This contacts initiates “off position.” In the “off positon” the recording on the portable recording device is stopped, the wireless network communication is ended and the device is placed in an energy conservation state.
While the portable video recording device is activated, the wireless network communication is activated and the recording can be automatically or manually initiated. The portable video recording device serves as an access point or client and the recording video data may be viewed “live” externally by multiple users interfacing with a wireless communication device, such as, a tablet, phone or other smart device over a wireless network. The user can not only view the recorded data but have the ability to control the data as well.
The foregoing and/or other aspects and utilities of the present general inventive concept may also be achieved by providing a computer readable medium having encoded thereon processor instructions that, when executed by a processor, performs a method of portable video recording. The processor executes processing instructions that interconnect the portable video controller and wireless communication device.
These and/or other aspects and utilities of the present general inventive concept will become apparent and more readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings, of which:
Reference will now be made in detail to the embodiments of the present general inventive concept, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. The embodiments are described below in order to explain the present general inventive concept by referring to the figures.
While specific examples are provided for portable video recording devices, the application describe herein is not limited thereto. The portable video recording device is intended to cover means to display, communicate and view interactions, typically during the conduct of an interview for the purposes of this application.
Implementation details of certain embodiments of the invention are described below by way of more specific functional components.
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When the portable video recording device casing module's variable hinge 4 is positioned in its initial “off position” no recordings are taking place and the device is in a low power or off operational state. This occurs when the position of the casing module 1 is in contact with the lower foundational support 2, to the extent that there is contact between the magnet 6 and the embedded magnetic switch 11. In an embodiment a sensor system is used to identify the contact between the casing module 1 and the lower foundational support 2. The interview recording process begins when the portable video recording device casing module's variable hinge 4 is adjusted in an upward position away from the lower foundational support 2, an “unfolding position”, as in
The portable video recording device also controls the recording process through the use of the start /stop button 12. When the portable video recording device is in its “on position” the recording device is active. When it is desired to start, pause or otherwise stop a recording while the portable video recording device is still in its “on position” the start/stop button 12 may be pressed and the current recording can be stopped or started based on the desires of the user. The operational indicator is in an active state.
When the portable video recording device is in the “off position” it is powered down. The portable video recording device also uses a low power and a sleep operational state. These states of operation assist in preserving the battery power of the device.
The casing module 1 includes a microprocessor. The microprocessor within the casing module 1 performs video compressions. In another embodiment the video compression can be implemented using separate hardware located in the camera module or alongside the microprocessor. The memory used by the microprocessor is used to execute the computer readable instructions. The casing module which also includes the camera 14. When the camera 14 is recording the operation indicator 8 will light, indicating the recording is underway, representing the active recording indicator state. The operational indicator 8 may be visual or audio, such as an LED or other indicating light or notification indicator of the video recording device recording activity.
In another embodiment the portable video recording device may operate as a Wi-Fi access point or a client on a local or enterprise Wi-Fi network. The portable video recording device has an access point mode and client mode. In this embodiment, the default state of the portable video recording device is to operate as a standalone access point. As a standalone access point, the portable video recording device is capable of providing the means for a client smart device or other external device to connect directly for video and audio streaming. The portable recording device exchanges operational command and operational control information using a wireless or network transmission. The communication of the video and audio streaming data is capable of real-time video and audio transmission to the client smart device or other external device. The portable video recording device is capable of automatic selection of the client or access point mode based upon the availability of the selected external network. The external network may be a local or enterprise network. When the external local or enterprise network is available, the portable video recording device will connect to the external network by default. This is the client mode. When the external network is not available or is out of range the portable video recording device will automatically switch to access point mode and provide a standalone network for the client smart device or another external device to use. The portable video recording device is configured to connect to local area or enterprise Wi-Fi network access point. The portable recording device is also capable of acting as a client on an alternate network rather than a standalone access point.
The memory card reader 5 utilizes removable memory cards. For example, Micro SD Flash cards may be used. The card is inserted from outside of the portable video recording device into the memory card reader 5. This makes the stored data located on the memory card easily accessible and provides a simple means of archiving data. The use of the memory card with the memory card reader 5 allows the portable video device to preserve the data recordings until the user chooses to remove them from the portable video recording device. This feature is an asset should the chain of custody of recorded data be deemed necessary, only the memory card would be required and not the entire portable video recording device. This approach also provides proper storage of recorded data for easy access by the user.
The recorded data is watermarked. The recorded data is also stored on the memory card located in the memory card reader 5. The watermarking can include visible video watermarks, such as, but not limited to date, time, name, location, and authentication code. The authentication process uses an identifier for the watermarked video recordings. The identifier is displayed to the user.
The portable video recording device communicates with wireless communication devices such as, but not limited to, tablets, PDAs, cellphones, smart devices or laptops, as depicted in
The wireless communication device allows the user to view the recorded data from the portable video recording device. The wireless communication device, as depicted in
Certain embodiments of the present general inventive concept provide for the functional components to manufactured, transported, marketed and/or sold as processor instructions encoded on computer-readable media. The present general inventive concept, when so embodied, can be practiced regardless of the processing platform on which the processor instructions are executed and regardless of the manner by which the processor instructions are encoded on the medium.
It is to be understood that the computer-readable medium described above may be any medium on which the instructions may be encoded and then subsequently retrieved, decoded and executed by a processor, including electrical, magnetic and optical storage devices, and wired, wireless, optical and acoustical communication channels. The computer readable medium may include either or both of persistent storage, referred to herein as “computer-readable recording media” and as spatiotemporal storage, referred to herein as “computer-readable transmission media”. Examples of computer-readable recording media include, but not limited to, read-only memory (ROM), random-access memory (RAM), and other electrical storage; CD-ROM, DVD, and other optical storage; and magnetic tape, floppy disks, hard disks and other magnetic storage. The computer-readable recording media may be distributed across components, to include such distribution through storage systems interconnected through a communication network. The computer-readable transmission media may transmit encoded instructions on electromagnetic carrier waves or signals, or as acoustic signals through acoustically transmissive media. Moreover, the processor instructions may be derived from algorithmic constructions of the present general inventive concept in various programming languages, the mere contemplation of which illustrates the numerous realizable abstractions of the present general inventive concept.
The descriptions above are intended to illustrate possible implementations of the present invention and are not restrictive.
Number | Date | Country | |
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62231358 | Jul 2015 | US |