Source: http://www.google.com/patents/US20020015362?dq=3657699
Timestamp: 2015-04-28 01:04:37
Document Index: 312677675

Matched Legal Cases: ['ART 1204', 'ART 1204', 'ART 1204', 'ART 1204', 'ART 1204', 'ART 1204']

Patent US20020015362 - Personal audio player with a removable multi-function module - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign inAdvanced Patent SearchPatentsA digital audio player has a removable and interchangeable multi-function module that has at least one operating member. The multi-function interchangeable module interoperates with the body of the digital audio player to provide a plurality of features, which include, but are not limited to, additional...http://www.google.com/patents/US20020015362?utm_source=gb-gplus-sharePatent US20020015362 - Personal audio player with a removable multi-function moduleAdvanced Patent SearchPublication numberUS20020015362 A1Publication typeApplicationApplication numberUS 09/881,900Publication dateFeb 7, 2002Filing dateJun 14, 2001Priority dateJun 15, 2000Also published asUS6606281Publication number09881900, 881900, US 2002/0015362 A1, US 2002/015362 A1, US 20020015362 A1, US 20020015362A1, US 2002015362 A1, US 2002015362A1, US-A1-20020015362, US-A1-2002015362, US2002/0015362A1, US2002/015362A1, US20020015362 A1, US20020015362A1, US2002015362 A1, US2002015362A1InventorsClayton Cowgill, John Marshall, Phil Johnson, Michael WaltersOriginal AssigneeCowgill Clayton N., John Marshall, Phil Johnson, Michael WaltersExport CitationBiBTeX, EndNote, RefManReferenced by (10), Classifications (6), Legal Events (15) External Links: USPTO, USPTO Assignment, EspacenetPersonal audio player with a removable multi-function module
DETAILED DESCRIPTION OF THE INVENTION [0031]FIG. 1A is a perspective view of an embodiment of a digital audio player 100 including a body 102 and a removable multi-function module (�module�) 104 in accordance with the present invention. As shown in FIG. 1, the outer surface of the body 102 comprises a display unit 108, control buttons 110, and a data interface 112. In accordance with the present invention, the digital audio player 100 is capable of performing a variety of functions. As shown below, each embodiment of the module 104 possesses a single or multiple functions. The embodiments of the module 104 are interchangeably coupled to the body 102 according to a user's needs. [0032]FIG. 1B is a perspective view of the removable multi-function module 104. FIG. 1B illustrates the module 104 includes an interface 122. The interface 122 couples the module 104 to the body 102. As describe below, the module 104 comprises at least one operating members to perform a single or multiple functions. For example, a battery 105 is shown as part of the module. [0033]FIG. 2 is a block diagram further illustrating the components in the digital audio player 100. The body 102 includes an audio output 106, the display unit 108, the control buttons 110, the data interface 112, an input/output port 114, a ROM (Read Only Memory) 116, a RAM (Random Access Memory) 118, a combined Digital Signal Processor and controller (�DSP�) 120 and an interface and control module 128. The above referenced components in the body 102 are coupled by a data bus 130. Those skilled in the art will recognize that these components may be coupled in other ways. For example, the ROM 116, the RAM 116 and the DSP 120 may be combined together on a single chip; or the ROM 116 and the RAM 116 may be integrated on one chip. The digital audio player 100 may further comprise a headset 127, which is coupled to the audio output 106. [0034] The module 104 includes the interface 122 and a first operating member 124 and a second operating member 126. The two operating members are both coupled to the interface 122. The operating members 124 and 126 are provided for performing additional functions for the digital audio player 100. As will be described below, the operating members 124 and 126 can be implemented in a variety of forms to provide multiple functions for the digital audio player 100. For example, the operating member 124 may be a battery providing power to the digital audio player 100, and the operating member 126 may be a memory storage device to store music or other data files. [0035] It should be understood that alternate embodiments of the module 104 may include only one operating member to perform a single function to the digital audio player 100. Such an alternate embodiment with a single operating member is still interchangeable with other embodiments including one or more than one operating members. [0036]FIG. 3 is an illustration of the interface and control module 128 in the body 102 and the interface 122 in the module 104. The first operating member 124 and the second operating member 126 in the module 104 are coupled to the body 102 via the interface 122. In one embodiment in accordance with the present invention, the interface 122 may be a conventional male 32-pin connector. The interface and control module 128 is the corresponding female 32-pin connector. Each of the pins within the 32-pin connector is assigned for a specific purpose. For example, pins 1 and 3 are used for the battery power; pins 10 and 11 are used for address line 11; pins 20 and 22 are used for data line. Those skilled in the art will recognize that various other connectors could be used for the interface such as a 64-pin connector. [0037] The interface 122 in the module 104 and the interface and control module 128 in the body 102 enable the body 102 to operate with a variety of operating members, for example, the operating member 124 and 126 in the module 104. For example, when a new type of the module 104 is coupled to the body 102, the DSP 120 within the body 102 is configured to recognize the new module; then the body 102 may receive power from a battery through the pins 1 and 3 as represented by line 1 of the connection 150 shown in FIG. 3. The body 102 may also read data from the second operating member 126 through the pins 20 and 22 as represented by lines 2-13 of the connection 150 shown in FIG. 3. Likewise, the body 102 operates with a plurality of embodiments of the module 104 that include different operating members without changing the interface and control module 128 and the interface 122. Therefore, as further illustrated below, the present invention provides interchangeable multi-function modules to operate with a digital audio player. To achieve a new function for a digital audio player, a user may simply remove one multi-function module and use another module with a desirable function. [0038]FIG. 4 illustrates a first embodiment of a module 104 a that includes a battery 402 in accordance with an embodiment of the present invention. The module 104 a with the battery 402 provides power to the digital audio player body 102 via the connection 150. In one embodiment, the battery 402 may be a conventional Alkaline battery, a NiMH battery or a Lithium Ion battery. The module 104 a may be the default module for the digital audio player 100. This embodiment provides a user a great convenience to choose different types of batteries for a digital audio player. For example, a user may select a module 104 a which is compatible with a Lithium Ion battery for its long run time. As described below, a user may also choose a module using a rechargeable NiMH or Lithium Ion battery for repeated usage. [0039] Unless otherwise indicated, the battery 402 can also be used as a power source with other operating members in other embodiments in accordance with the present invention even though it may not be explicit that a battery 402 or a power source is included in the embodiments described herein. [0040] Likewise, it should be understood that the operating members 124 and 126 in the embodiments described hereinafter may also be used in combination with each other dependent upon the functions and features needed by users. [0041]FIG. 5 shows a second embodiment of module 104 b including a recharging circuit 502, a rechargeable battery 506, the interface 122, a connector 508, and an operating member 526 in accordance with the present invention. The recharging circuit 502 is capable of being coupled to an external power supply 504 via a conventional connector 508. When the rechargeable battery 506 is at low power level, the recharging circuit 502 recharges the battery 506. The recharging circuit 502 is of a conventional type known to those skilled in the art. One of ordinary skill in the art would recognize that there are different commonly known techniques to implement the battery recharging function. [0042]FIG. 6 illustrates a third embodiment of a module 104 c which includes a memory device 602 and a battery 624 in accordance with the present invention. In a preferred embodiment, the memory device 602 is a flash memory. Flash memories may be packaged as �flash cards� in several formats, including the full-size PC Card and the smaller CompactFlash, SmartMedia or similar formats. There are two types of flash interfaces: the earlier linear flash, which requires Flash Translation Layer (FTL) or Flash File System (FFS) software to make it look like a disk drive to a digital signal processor; and the ATA interface, which has been widely used for hard disks and has the same 512-byte block (sector) size. One skilled in the art would recognize either of these or various other implementations of the flash memory interfaces described above in practicing this aspect of the present invention. [0043] During the operation of the digital audio player 100, when the module 104 is attached to the body 102, the DSP 120 sends a probing signal through the body interface 128 and the module interface 122. After the probing signal detects the existence of the memory device 602 in the module 104, the DSP 120 determines the type and size of the memory device 602. The DSP 120 further assigns addresses to the memory device 602 so that the DSP 120 addresses the memory device 602 and performs data operation such as reading data from or writing data into the memory device 602. In a preferred embodiment, the type of memory device 602 is the same as that of the RAM 118 in the body 102. For example, the RAM 118 is a 32 MB MMC memory and the memory device 602 is a 64 MB MMC memory card. [0044] The advantage of this embodiment is to provide a convenient mechanism for memory expansion for the digital audio player 100. When a user wants to expand the music storage capability, he or she may simply use a module 104 c which has a larger memory device 602. Further, since the module 104 c is interchangeable with any other modules herein described, when a user does not need the additional memory storage, the user may conveniently replace the module 104 c with any other multi-function modules. [0045]FIG. 7 shows a fourth embodiment of a module 104 d including the interface 122, a power source 724 and a memory interconnect socket 702 for receiving compatible types of memory devices in accordance with an embodiment of the present invention. For example, the flash memory cards, such as MMC�, Smartmedia�, CompactFlash� flash memory cards or Sony� memory stick�, or any other market general-use flash memory media, may be inserted into a compatible memory interconnect socket 702 to provide optional memory storage for the digital audio player 100. This embodiment is particularly useful because it allows different digital devices to share the use of digital memories. For example, a user may easily erase the digital image files that are taken by a digital camera and stored on a CompactFlash card; and later insert the card into a CompactFlash compatible memory interconnect socket on the module 104 d to make it available for the digital audio player 100. Alternately, different CompactFlash memories may be used to store different music, and then the user may easily change the music available by inserting or removing different CompactFlash memories from the memory interconnect socket 702. [0046] The memory interconnect socket 702 is a commercially available product, for example, a Tyco Electronics MMC connector. The memory interconnect socket 702 is coupled to the interface 122 in commonly known techniques. For example, a MMC interconnect socket 702 is coupled to the interface 122 by serial lines. [0047]FIG. 8 shows a module 104 e including a power source 824 and a mass storage module 801 according to an embodiment of the present invention. The mass storage module 801 includes a mass storage device 802 and an interface logic 804. The mass storage module 801 is coupled to the interface 122 through a signal line 808. [0048] The mass storage module 801 provides a large storage capacity for the body 102. In accordance with one aspect of the present invention, the body 102 may quickly and conveniently access the data in the mass storage device 802. [0049] In the embodiment as illustrated in FIG. 8, the mass storage device 802 comprises a miniature hard drive, e.g., a microdrive manufactured by IBM Microdrive� technology, which offers a removable high capacity storage ranging from 340 MB to 1 GB in a one-inch hard disk drive at much lower cost. Other alternate embodiments of the mass storage device 802 include an optical disk, a non-moving high density storage device or a rotating media. The embodiment shown in FIG. 8 provides a cost-effective means to significantly expand the storage size of the digital audio player 100. These mass storage devices store large size of digital music files at a lower cost than the flash memory cards. [0050] As further illustrated in FIG. 8, the interface logic 804 is coupled between the interface 122 and the mass storage device 802. The function of the interface logic 804 is to perform a translation of data from the module bus format to a format suitable for the mass storage device 802. The interface logic 804 may be a CPLD (Complex Programmable Logic Device), FPGA (Field Programmable Gate Array), ASIC (Application Specific Integrated Circuits), a microprocessor, a microcontroller, or discrete logic. For example, if the mass storage device 802 as in the case of connecting an IDE/ATA type laptop hard drive to the body 102, it requires that an 8-bit wide data bus 808 for the module 104 e be converted into a 16-bit wide data bus 806 for the IDE interface and the IDE registers are mapped into the body 102's memory space. After the hard drive is memory-mapped into the body 102 address space, the body 102 directly controls the hard drive. [0051]FIG. 9 illustrates a sixth module 104 f that includes a mass storage device in accordance with the present invention. The module 104 f includes the interface 122 and a mass storage device 901. The mass storage device 901 includes a miniature hard drive 902, an interface logic 908, a secondary microprocessor 904, and a buffer memory 908. [0052] In this embodiment, the secondary microprocessor 904, for example, an ARM7TDMI control processor, is used to handle all the low-level transactions with the miniature hard drive 902. The secondary microprocessor 904 thus handles the mass-storage management tasks which are performed by the digital signal processor 120. As a result, it reduces the firmware setting on the body 102. [0053] The secondary microprocessor 904 also supports the additional buffer memory 908 for buffering data for the miniature hard drive 902. The buffer memory 908, which is, for example, a 16 MB SDRAM (Synchronous Dynamic RAM), allows for faster buffering the music data stored in the miniature hard drive 902 and consequently a more frequent power-down for the miniature hard drive 902, thus saving the power and the overall battery life. [0054] The body 102 and the secondary microprocessor 904 communicate through the interface logic 906 by means of a message �mailbox� scheme where the interface logic 906 acts as a small dual-port memory where commands and data are transmitted between the body 102 and the module 104 f. [0055] In one embodiment, the miniature hard drive 902 is an IBM Microdrive product. The miniature hard drive 902 can be replaced with other massive storage devices, such as optical disks, e.g., a Dataplay� optical disk media, which provides up to 500 MB storage space. Those skilled in the art would know the implementation of the present invention upon the embodiments which use other massive storage devices. [0056]FIG. 10 shows a seventh module 104 g including a display unit 1002 and a power source 1024 in accordance with the present invention. The display unit 1002 may be a LCD (Liquid Crystal Display) device. [0057] In accordance with one aspect of the present invention, the additional display unit 1002 on the module 104 g provides the digital audio player 100 with a display option adapted to the consumer needs. For example, if the size of the display unit 108 on the body 102 is not large enough for certain purpose, e.g., displaying lyrics while playing the music, a larger LCD screen on the module 104 g is desirable. In addition, the DSP 120 may be programmed to display clock information and time alarm on the LCD screen on the module 104 g. Thus, the digital audio player 100 can be used as a multi-functional digital alarm clock. [0058]FIG. 11 shows yet another embodiment of a module 104 h which includes an FM tuner 1101, an antenna 1105 and a power source 1124 according to the present invention. The FM tuner 1101 is connected to the body 102 through the module interface 122. The FM tuner 1101 is also coupled to the antenna 1105. [0059] As shown in FIG. 11, the FM tuner 1101 further comprises an FM tuner circuit 1108, an Analog/Digital (A/D) converter 1106, a microcontroller 1104 and an interface logic 1102. [0060] In one embodiment, the FM tuner circuit 1108, for example, a Philips TEA5759, receives FM signals from the antenna 1105, which is a conventional component used for FM radio reception. The FM tuner circuit 1108 is further connected with proper anti-aliasing filter and level adjustment to a two-channel serial A/D converter 1106. The A/D converter 1106 converts the analog audio outputs from the FM tuner circuit 1108 into an uncompressed digital stream. The A/D converter 1106 and the FM tuner circuit 1108 are controlled by a microcontroller 1104. The microcontroller 1104, for example, an 8-bit Atmel AT90S1200 RISC chip, instructs the FM tuner circuit 1108 to tune to particular channels, and collects the uncompressed samples from the A/D converter 1106. [0061] The microcontroller 1104 communicates to the body 102 through the interface 122 by way of the interface logic 1102. In one embodiment in accordance with the present invention, the interface logic 1102 is a CPLD, which comprises 32 macrocells. The interface logic 1102 provides two 10-bit registers for the microcontroller 1104 so that the microcontroller 1104 places a pair of stereo, 10-bit samples into the Left and Right sample registers at each time constant (1/44100th of a second, for example). When all 10 bits of each sample have been latched into the interface logic 1102, an interrupt is generated to the body 102 by the interface logic 1102 over the module interface 122. The interrupt signals the body 102 to retrieve the data and play it through the digital audio player 100's output signal processing. [0062] To control the operation of the FM tuner 1101, the body 102, in particular, the DSP 120, sends a single (N-bit) command at a time to the microcontroller 1104 through the interface logic 1102. Writing the command register in the interface logic 1102 by the body 102 results in the �/MSG� line asserting on the interface logic 1102 which triggers an interrupt alerting the microcontroller 1104 that it has received a command and acts according to the command. The commands sent by the body 102 include entering and exiting low power mode, tuning the radio, setting or moving to a preset station, returning the state of the FM radio such as tuned, not-tuned, mono, or stereo, etc. Commands that require more than one byte can be accommodated by multiple writes to the register in the interface logic 1102. [0063] During the operation of the FM tuner module 104 h, the FM stereo radio signal may be sampled at 44.1 KHz and each sample is read and written into the interface logic 1102 within approximately 22.5 us. If the 44.1 KHz interrupt rate overloads the interface logic 1102, the sampling rate can be reduced to 32 KHz. Alternatively, to avoid the overloading problem, a larger CPLD chip may be used for the interface logic 1102 and 2-3 samples of FIFO are provided by reducing the interrupt rate by 2 or 3 times. [0064] In one embodiment of the FM tuner 1101, the microcontroller 1104 may be an ARM processor, e.g., the ARM7TDMI. One of ordinary skills in the art would also recognize to use other commercially available products to suffice the I/O usage requirement for the interface logic 1102 and the microcontroller 1104. In accordance the present invention, the microcontroller 1104 may be eliminated entirely if the interface logic 1102 is replaced by an FPGA running a state machine to control the peripherals. [0065] In addition, for the embodiment shown in FIG. 11, if the power source 1124 is a Lithium Ion battery with a recharge controller, the microcontroller 1104 communicates with the 2-wire interface on a recharge controller and provides accurate battery �gas gauge� functionality to the body 102. For non-Lithium Ion batteries, in one embodiment, an A/D converter 1106 with more than two channels (or add an external analog Multiplexor) directly reads the battery voltage on an Alkaline or NiMH battery. [0066]FIG. 12 shows a module 104 i including a power source 1224, the interface 122, and an Infrared (IR) transceiver 1201. In one embodiment in accordance with the present invention, the IR transceiver 1201 is an IrDA (Infrared Data Association) port. Supported by the IrDA Serial IR physical layer (IrDA-SIR), the IR transceiver 1201 may provide a half-duplex connection of up to 115.2 Kbps with an external IrDA device 1206. One of ordinary skills in the art would recognize to implement the IR transceiver 1201 to transfer data with external IrDA devices in higher speed. The advantage of this IR transceiver module 104 i is to provide an new input/output interface so that the digital audio player 100 can wirelessly exchange data with other devices having IR interface, such as an mobile computer or a handheld device, without a parallel cable or USB cable connection. In this way, the digital audio player 100 can be integrated in a personal area network (PAN) for other advanced applications. For example, with the IR transceiver module 104 i, the digital audio player 100 may �beam� the files stored in its memory to a mobile computer; the mobile computer may send software updates into the digital audio player 100 through the IR transceiver 1201. [0067]FIG. 12 further shows that the IR transceiver 1201 includes an IR Receiver and Transmitter Module 1202 and a UART 1204 (Universal Asynchronous Receiver Transmitter) with IR transceiver support. [0068] The UART 1204 is a low power circuit that makes up a serial port and converts parallel bytes from a microprocessor into serial bits for transmission, and vice versa. During the operation, the DSP 120 in the body 102 is configured to implement applicable IrDA protocols, such as Infrared Link Access Protocol, to control the data to transmit over the interface 122 and deliver the data in parallel to the UART 1204. The UART 1204 serializes the data and sends it out as modulated IR pulses to the IR Transmitter portion in the IR Receiver and Transmitter Module 1202, which in turn transmits the data to the external IR device 1206. [0069] Data received from the external IR device 1206 is demodulated by the IR Receiver portion of IR Receiver and Transmitter Module 1202 and sent in serial to the UART 1204. The UART 1204 then converts the serial stream into parallel data, which are made available to the body 102 over the module interface 122. To achieve faster IR transmission speed, one of ordinary skilled in the art would recognize to use non-UART components for high-speed extensions. [0070]FIG. 13 further shows a module 104 j including the interface 122, a power source 1324, a wireless transceiver 1302 and an antenna 1304. [0071] The wireless transceiver 1302 enables the digital audio player 100 to communicate with other wireless devices using radio frequency or other commonly known techniques. In one embodiment, the wireless transceiver 1302 receives radio frequency signals from an external wireless device 1306, which detects the heart beats of a human being. The wireless transceiver 1302 converts the radio frequency signals representing the heart beats into digital signals and sends them to the DSP 120 over the interface 122. The DSP 120 is configured to process the digital signals and to calculate the corresponding heart rate and to display the result on its display unit 108. Thus, the digital audio player 100 with the wireless transceiver module 1302 becomes a heart rate monitor, which is convenient for a person who carries the digital audio player while exercising in a fitness room or having physical training outdoors. [0072]FIG. 14 illustrates a module 104 k including an alternative embodiment 104 k which also enables the digital audio player to wirelessly communicate with another wireless device. [0073]FIG. 14 illustrates that the module 104 k includes a two-way radio module 1400. The function of the module 104 k is to make the digital audio player 100 become a two-way radio electronics product. A user may conveniently use this module 104 k with the digital audio player 100 to talk to another user within certain range via radio signals. [0074] In one embodiment, the two-way radio module 1400 includes a Wireless Transceiver 1402, a Multiplexer (MUX) 1409, a Analog to Digital (A/D) converter 1405, a Digital to Analog (D/A) converter 1407, a Microcontroller 1403, a Interface Logic 1401, and a Digital Audio Input. 1411. FIG. 14 shows that the module 104 k may also include a power source 1424 and an Antenna 1404. [0075] The Wireless Transceiver 1402 is coupled to the MUX 1409. The MUX 1409 is respectively coupled to the A/D converter 1405 and the D/A converter 1407. The A/D converter 1405 and the D/A converter 1407 are coupled to the Microcontroller 1403 and the Interface Logic 1401 through an address bus and a data bus. The Digital Audio Input 411 is coupled to the Microcontroller 1403. [0076] During the operation of the digital audio player 100 with the module 104 k, the DSP 120 may be configured to control a two-way radio �talk� or �listen� mode. In a �talk� mode, the Digital Audio Input 1411, which may be a digital microphone, converts a user's voice into digital data stream. The Microcontroller 1403 further delivers the digital data stream to the D/A converter 1407, wherein the digital data stream is converted into analog signals. The multiplexer 1409 routes the analog signals to a transmitter in the wireless transceiver 1402. Through the Antenna 1404, the transmitter broadcasts the analog signals at a pre-selected channel to a Wireless Radio Device 1406. In a �listen� mode, the DSP 120 instructs a receiver in the Wireless Transceiver 1402 to receive analog signals from the Wireless Radio Device 1406. The Wireless Transceiver 1402 then feeds the analog signals into the Multiplexer 1409. The Multiplexer 1409 demodulates the analog signals and sends them to the A/D converter 1405, which converts the analog signals into digital data streams. The Microcontroller further transmits the digital data streams to the body 102 through the Interface Logic 1401 and the connection 150. Thus, a user may hear another user speaking to the Wireless Radio Device 1406 through the audio output 106. [0077] It should be noted that if the two-way radio module 1400 is full-duplex, i.e., the Wireless Transceiver 1402 transmitting and receiving signals simultaneously, the MUX 1409 may not be needed. The A/D converter 1405 and the D/A converter 1407 may be directly coupled to the Wireless Transceiver 1402. [0078] The two-way radio module 104 k advantageously adds an appealing function to the digital audio player 100. A user does not need to buy a separate two-way radio product and simply places the two-way radio module to the body 102. A digital audio player 100 instantly becomes a two-way radio device. [0079] It is to be understood that the specific mechanisms and techniques that have been described are merely illustrative of one application of the principles of the invention. Numerous additional modifications may be made to the embodiments described above without departing from the true spirit of the invention. Furthermore, new embodiments may be made by combining operating members from the described embodiments. For example, an alternate embodiment comprises an FM tuner and a flash memory card, which have been respectively described in FIG. 11 and FIG. 6. Another embodiment may include the mass storage device as illustrated in FIGS. 8 and 9 and the IR transceiver as illustrated in FIG. 12. None of the operating members in the described embodiments are exclusive from each other. Referenced byCiting PatentFiling datePublication dateApplicantTitleUS7191193Jan 2, 2003Mar 13, 2007Catch MediaAutomatic digital music library builderUS7756915Feb 20, 2007Jul 13, 2010Catch MediaAutomatic digital music library builderUS7761176 *Nov 23, 2004Jul 20, 2010Catch Media, Inc.Promotional portable music playersUS8644969Jun 30, 2009Feb 4, 2014Catch Media, Inc.Content provisioning and revenue disbursementUS8666524Apr 21, 2004Mar 4, 2014Catch Media, Inc.Portable music player and transmitterUS8732086Jul 16, 2004May 20, 2014Catch Media, Inc.Method and system for managing rights for digital musicUS8832161Jun 21, 2011Sep 9, 2014Google Inc.Interface for extending functionality of memory cardsUS8918195Dec 1, 2006Dec 23, 2014Catch Media, Inc.Media management and trackingWO2006058149A2 *Nov 22, 2005Jun 1, 2006Catch Media IncPromotional portable music playersWO2010088607A1 *Feb 1, 2010Aug 5, 2010Marc LaverdiereTouch music player* Cited by examinerClassifications U.S. Classification369/11, 369/12International ClassificationG11C7/16Cooperative ClassificationG11C7/16, G11C2207/16European ClassificationG11C7/16Legal EventsDateCodeEventDescriptionOct 4, 2011FPExpired due to failure to pay maintenance feeEffective date: 20110812Aug 12, 2011LAPSLapse for failure to pay maintenance feesMar 21, 2011REMIMaintenance fee reminder mailedMay 10, 2010ASAssignmentOwner name: CITIBANK, N.A., AS NOTES COLLATERAL AGENT,NEW YORKFree format text: SECURITY AGREEMENT;ASSIGNOR:SIGMATEL, LLC;US-ASSIGNMENT DATABASE UPDATED:20100511;REEL/FRAME:24358/439Effective date: 20100413Owner name: CITIBANK, N.A., AS NOTES COLLATERAL AGENT,NEW YORKFree format text: SECURITY AGREEMENT;ASSIGNOR:SIGMATEL, LLC;US-ASSIGNMENT DATABASE UPDATED:20100518;REEL/FRAME:24358/439Effective date: 20100413Free format text: SECURITY AGREEMENT;ASSIGNOR:SIGMATEL, LLC;US-ASSIGNMENT DATABASE UPDATED:20100525;REEL/FRAME:24358/439Free format text: SECURITY AGREEMENT;ASSIGNOR:SIGMATEL, LLC;REEL/FRAME:24358/439Free format text: 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