The present invention generally relates to a docking station and more particularly relates to a docking station for a portable device.
Various docking stations are known for portable devices. For example, U.S. Pat. No. 6,591,085 issued to Grady describes a modular docking unit for an iPod® that can engage and disengage from various types of supporting power/charging adapters, including a pedestal, a cigarette lighter adapter, a wall mount and a desk mount. The modular docking unit includes an FM transmitter and power supply/charging circuitry electrically coupled to the iPod®. The power supply/charging circuitry transmits electrical power through the modular docking unit to power/charge the iPod®. The power/charging circuitry thereby provides electrical power for charging the iPod® battery. The FM transmitter transmits the audio content played by the iPod® for reception and play by a remote radio receiver, such as a car radio. A coupling means in a docking cavity connects the iPod® with the circuitry of the FM transmitter and power/charging assembly.
A docking station having a flexible support for holding a media player is also known. Belkin® Corporation offers a device called Tunebase® for iPod® mini (Part # F8V7098), which operates through a cigarette lighter outlet within the car. Tunebase® has a holder with a flexible-steel neck for positioning the iPod® mini safely while driving. While mounted in the Tunebase®, the iPod® mini is powered and charged simultaneously.
With the ever increasing availability of various portable devices, there exists a continuing need for improving functionalities and operation of docking stations.
Briefly, according to one aspect of the invention, a docking station for a portable device, which is electrically coupleable to an external power supply, comprises a base having a cup-shape to facilitate portability of the docking station and its ease of use. The docking station includes a docking cavity for docking the portable device. A mating connector disposed in the docking cavity provides electrical interconnection between the docking station and the portable device, and a flexible support between the base and the docking cavity provides for electrical coupling between the mating connector and the external power supply. A base adjustment sleeve can also be used with the docking station of the present invention for adjusting a physical dimension of the cup-shaped base as necessary.
According to another aspect, the docking station comprises a base that attaches to a device holder via a support, e.g., a flexible support, for holding the portable device. A docking cavity is removably attachable to the device holder. The docking cavity can be integrated with the housing of the portable device or include a clip device that is used to removably attach the docking cavity to the device holder.
According to still another aspect of the present invention, a docking station accommodates differently sized portable devices via a fitting adapter. The fitting adapter is insertable into the docking cavity to support holding portable devices of different sizes by providing for expansion or restriction of the docking cavity. A retainer disposed on the docking cavity can be used for securing the fitting adapter against the docking station.
According to some of the more detailed features of the invention, the docking station includes a transmitter for transmitting signals generated by the portable device to a remote receiver. According to yet another aspect of the invention, an antenna for the docking station includes a conductor that radiates radio frequency signals and a suction-cup that is attached along the length of the antenna conductor for positioning the antenna on a surface, preferably in close proximity of the antenna of the remote receiver.
According to other more detailed features of the invention, power circuitry coupled to the external power supply energizes the portable device. The power circuitry can include charger circuitry for charging one or more batteries of the portable device. A control circuitry controls one or more functions of the docking station, including a user interface function or a data exchange function between the portable device and the docking station. Among others, the mating connector supports a port interface comprising one or more of a universal serial bus (“USB”) port, a Firewire® port, an iPOD® port or a personal digital assistant (“PDA”) port interface.
In describing the exemplary embodiments of the present invention illustrated in the drawings, specific terminology is employed for the sake of clarity. However, the invention is not intended to be limited to the specific terminology so selected. It may be understood that each specific element includes all technical equivalents that operate in a similar manner to accomplish a similar purpose.
As shown, according to one embodiment of the invention, the docking station 100 has a cup-shaped base 104 and a docking cavity 106. The base 104 which has a cup shape can comprise any of a wide variety of rounded, concave bowl shapes characterized by a hollow interior portion, which can have a rounded circular shape or a rounded non-circular horizontal cross section, including substantially conic, cubic, or cylindrical shape.
The elongated flexible support 110 is bendable, adjustable, and movable, thus allowing a user to position the docking cavity 106 to a desired location. The elongated flexible support 110 substantially maintains its shape and allows the portable device 102 to be supported and positioned at the desired location. This configuration of the invention allows the user to place the portable device 102 at a location that may, for example, be at a safe distance that allows for the portable device to be manipulated while driving an automobile or a moving vehicle. Thus, the flexible support 110 allows for adjustably positioning the docking cavity 106 in the perimeter of the cup-shaped base 104, for example, in a safe position when inside a vehicle. Optionally, a front lip spacer 109 is placed on the front lip of the cavity housing to further secure the portable electronic device.
In one embodiment of the invention, some or all of the circuitry of the docking station 100 is enclosed within the docking cavity housing 108. Such functional circuitry can include power, control, processor, as well as transmitter circuitry. The transmitter allows audio played by the portable device 102 to transmit on a selected channel and be heard on a properly tuned radio receiver. The processor provides circuitry for managing user interface functionality, including display and controls for setting the transmit channel of the transmitter. In addition, power or charger circuitry, as applicable, can energize the portable device 102. For example, a power jack 114 disposed on the cup-shaped base 104 is used for supplying power via an external power source 110. The external power source can be a cigarette lighter adapter (“CLA”) 116 or a wall cube power supply 117, an AC-to-DC power supply, with each supply having its corresponding cords and power plug for insertion into the power jack 114 of the docking station 100 to provide external power to the docking station for energizing the portable device 102. In one embodiment, wires that electrically interconnect the power supplied from the external power source 118 are passed through the cup-shaped base 104 and elongated flexible support 110 to the portable device 102 via a mating connector 120 in the docking cavity 106, as further described later. As such, the docking station acts as a straight-through power conduit to the portable device, which uses its own battery charger circuit to provide charge energy to the portable device. In another embodiment, the docking station itself can be equipped with charger circuitry for charging the portable device batteries. As described later in connection with
The docking station 100 according to this aspect of the present invention can also accommodate different size portable devices via appropriately designed fitting accessories or adapters, which can constrict or enlarge the docking space needed for accommodating different sizes. For example, through one or more corresponding adapters, the docking station can accommodate various sizes of iPod® players, which are offered in standard, “mini,” “nano” and “shuffle” sizes. In one embodiment, the docking station accommodates, a standard iPod® by inserting it into the docking cavity directly without any fitting adapter. For accommodating smaller sized iPods®, suitably sized fitting adapters are used, which reduce the cavity size. The fitting adapters are inserted into the docking cavity to create appropriately sized cavities that accommodate corresponding iPods®.
After the fitting adapter is inserted into the docking cavity, a retainer is used to secure it to the docking station. In the exemplary embodiment shown in
Referring back to
As shown in
As shown in
On the back side of the device holder 412 (shown in
The exterior of the base 704 includes indicator 712 and depressible user interface buttons 714, allowing the user to control the docking station and functions of the portable device. The base includes a power LED indicator to indicate when the plug of the base is fully inserted into the external CLA socket and is receiving power from the external DC source.
The base also includes a digital display 718 that indicates the radio frequency being used by the FM transmitter and to display the radio frequency while scanning. The base also includes a coupling mold 722 that is adapted to couple the base with the elongated flexible support 410 and the wire 726. The coupling mold physically secures the base to the elongated flexible support. The coupling mold also receives the wire for connection to the internal circuitry, as discussed below.
Examples of features controlled by the docking station include audio control information (e.g., pause, play, etc.), as well as requesting stored data to be transmitted to the docking station. Examples of control data sent from both the docking station and the portable device include request data, acknowledgement data, device detection data, communication setup data, error data, and other known networking and control data transmitted between devices prior to and during communication.
Another type of data exchanged between the docking station and the portable device is audio, which may be analog or digital. Audio signals generated by the portable device are applied to a transmitter 814 for transmission to the remote radio receiver. The transmitter modulates radio frequency carrier signals, preferably within the commercial band, e.g., AM, FM, S-band, X-band with the analog audio signal to generate radio frequency signals, which are radiated via an antenna 816. The radio frequency signals can be received by an external radio receiver, such as an AM, FM, or satellite band receiver of a car stereo, a home theater system, or any other radio frequency receiver.
The embodiments and examples discussed herein are non-limiting. The invention has been described in detail with respect to preferred embodiments, and it will now be apparent from the foregoing to those skilled in the art that changes and modifications may be made without departing from the invention in its broader aspects, and the invention, therefore, as defined in the appended claims, is intended to cover all such changes and modifications that fall within the true spirit of the invention.
This application claims the priority of Provisional Application No. 60/774,242, filed on Feb. 17, 2006, the subject matter of which is incorporated herein by reference.
Number | Date | Country | |
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60774242 | Feb 2006 | US |