Patent Application
20100184479
Not Applicable.
Not Applicable
Not Applicable
For a number of reasons, many digital devices having audio outputs and/or inputs do not have digital data outputs or inputs. This limits the types of accessories that can be developed for the devices. For example, an Apple iPhone can receive digital data through a cellular transceiver. However, iPhone lacks the ability to load executable files through a physical port on the device. While an accessory can be constructed that has a cellular transceiver, the components required to construct such an interface make accessories having such an interface economically unviable.
An embodiment of the present invention is directed toward a system for receiving data between a first and second device. The first device has a microprocessor, an audio input, an audio output, and an operating system. The second device has a microprocessor, an audio input, and an audio output. The first device is preferably a mobile phone, such as an Apple iPhoneâ„¢, or a similar portable media device. The second device is preferably a device for controlling the first device, such as a remote control or game control surface, or alternatively a device for enhancing the functionality of the first device such as an FM transmitter, voice recorder, or FM tuner.
The system includes software residing on the first device that monitors an audio input of the first device for a sequence of audio signals that represent a data transmission from an audio output of the second device. After the software determines a data transmission is taking place, the audio signals received by the first device are interpreted as digital data by the software in the first device. This activity is considered receiving an upstream data communication.
The system also includes software residing on the second device that monitors an audio input of the second device for a sequence of audio signals that represent a data transmission from an audio output of the first device. After the software determines a data transmission is taking place, the audio signals received by the second device are interpreted as digital data by said software in the second device. This activity is further described herein as receiving a downstream data communication.
The system also includes software residing on the first device that determines when data needs to be transmitted to the second device. Once this determination is made, the first device encodes the digital data into a sequence of audio signals and transmits the audio signals to the second device via an audio output on the first device. This activity is referred to as a transmission of a downstream data communication.
The system further includes similar software residing on the second device that determines when data needs to be transmitted to the first device. Once this determination is made, the second device encodes the digital data into a series of audio signals and transmits the audio signals to an audio input on the first device via an audio output on the second device. This activity is referred to as a transmission of an upstream data communication.
Another embodiment of the present invention is directed toward the transmission of digital data to an accessory from a portable electronic device, such as a mobile telephone, having a microprocessor, an audio input, an audio output, and an operating system. The accessory device includes a microprocessor, an audio input, and an audio output. The accessory device is preferably a device for enhancing the functionality of the portable electronic device, such as an FM transmitter, voice recorder, or FM tuner.
The portable electronic device includes software that determines when data needs to be transmitted to the accessory device. Once this determination is made, the software on the portable electronic device encodes the digital data to be transmitted into a series of audio signals and transmits the audio signals to the accessory device via an audio output on the portable electronic device. The frequency of the audio signals transmitted by the portable electronic device is preferably in the 19-20 kHz. The audio encoding process can be based on several methods, including generating the audio signals dynamically whenever data needs to be transmitted to the accessory, or by using a database of pre-rendered audio segments based on a common accessory command set to reduce the processing requirements on the portable electronic device.
The accessory device also includes software that monitors an audio input of the accessory device for a sequence of audio signals that represent a data transmission from an audio output of the portable electronic device. After the software determines a data transmission is taking place, the audio signals received by the accessory device are interpreted as digital data by the software in the accessory device in a downstream data communication. The audio decoding process can be based on several methods, including interpreting the audio signals dynamically into digital data whenever data is received, or comparing the audio received with a database containing common accessory commands to reduce the processing requirements on the accessory device.
Another embodiment of the present invention is directed toward a system for communicating digital data between a first and second device. The first device has a processor, an audio input, an audio output and an operating system. The system includes audio decoding software residing on the first device that monitors an audio input of the first device for audio signals representing digital data and decodes the audio signals into digital data when the audio signals are detected. Audio encoding software residing on the first device receives a digital data file and encodes the digital data into an audio file. Audio decoding software residing on the second device monitors an audio input of the second device for audio signals representing digital data and decodes the audio signals into digital data when the audio signals are detected. Audio encoding software residing on the second device that receives a digital data file and encodes the digital data into an audio file. The first device is preferably a mobile telephone and the encoding and decoding software is downloaded to the mobile telephone through a digital transceiver. The digital transceiver preferably includes an internet interface and the second device further comprises a digital input/output port such that internet data received from the first device can be transferred to a third device through the digital data input/output port. The second device is preferably a controller for the first device that includes control conversion software residing in the controller that generates audio control files based upon manipulation of controls on the controller. The audio control files are converted into digital control data for the first device by decoding software in the first device. Alternatively, the second device may be an FM transmitter for broadcasting an audio signal received from the first device to a FM stereo receiver or a voice recorder.
Another embodiment of the present invention is directed toward an accessory for an electronic device, such as an internet connected mobile phone, having a processor, a standard audio input jack and a digital data input. The accessory includes an audio file generator that generates an audio data file of frequency signals based upon digital data that includes an audio encoded version of the digital data. An audio output couples to the audio input of the electronic device to transfer the audio data file from the audio file generator to the electronic device. Software residing in the electronic device decodes the audio data file into a digital data file. The accessory has a digital data port for coupling to a computer. The accessory provides internet access to the computer through an internet interface on the electronic device. The software residing in the electronic device is downloaded to the device through the internet interface of the electronic device. The accessory includes an FM transmitter for transmitting audio from received from the electronic device to a FM stereo.
Yet another embodiment of the present invention is directed toward a method of communicating digital control data between an accessory and an electronic device having an audio input/output port. In accordance with the method, application software that is downloaded to the device through a digital data interface of the device. The digital data to be transferred from the accessory to the device is converted into an audio data file of selected frequency tones. The audio data file is transferred to the device through the audio input port of the device. The audio data file is converted back into the original digital data with the application software. To control the accessory, user inputs on the device are converted into digital control data for the accessory with application software, the digital accessory control data is converted into an audio file, the audio file is transferred to the accessory through the audio output of the device, the audio files are converted into digital data in the accessory and the control data is used to control a function of the accessory. The control data is preferably superimposed upon an existing audio output of the device. The accessory converts the existing audio output into a radio frequency modulated output and transmits the radio frequency modulated output to a remote FM stereo receiver.
A preferred embodiment of the present invention includes software residing in the accessory and device that convert digital data into audio files of various frequency audio tones and then processes the audio file to decode the digital data. These audio files can then be transferred through the audio input/output ports of the device and accessory. The use of the audio port to transfer digital data between the device and accessory allows the accessory to be constructed without the need for the expensive and complicated digital wireless communication chips and hardware. Much of this hardware is proprietary and restricted while the audio input/output of the devices are typically standardized around the standard audio jack.
Application software is downloaded from the internet to the mobile phone 4 through the mobile phone's wireless digital transceiver 10. The application software runs on the operating system of the mobile phone 4. The application software converts digital data to be sent to the accessory 2 into audio files having the data encoded in the form of a series of audio tones. The application software also converts audio files received from the accessory into digital data that can be utilized for any of a number of functions. The application software can be user initiated or examine all received audio for a series of audio tones that identify the audio input as an audio data file from the accessory 2.
The accessory can be any type of accessory or device that might need to communicate digital data to the accessory. For example, the accessory 2 may be an FM transmitter for transmitting audio outputs from the phone 4 to an FM stereo receiver 12. In such an embodiment, it is use to be able to use the phone controls to set the frequency of the FM transmitter. The phone 4 is controlled by the application software that is executed on its operating system software. The accessory 2 allows digital control data to be generated by the application software in the mobile phone 4 based on a user manipulating the controls 14 of the phone 4 and then transferred to the transmitting accessory in the form of a series of audio tones through the audio output port 6 of the phone 4. The accessory then interprets the received audio file and implements the corresponding control functions such as raising the output volume or setting the transmitter frequency.
When the accessory wants to communicate digital data to the device, the accessory processor 24 uses digital data to audio tone conversion software 34 to create an audio file having varying frequency tones that varied in accordance with a predetermined scheme to form an encoded version of the digital data. The audio file is then transferred to the device audio input port 30 through the accessory audio output 28. Audio tone to digital data conversion software 36 is executed by the device processor 38 to decode the received audio file into the original digital data. The digital data can then be used by any of the programs running on the device 22.
When the device 22 wants to communicate digital data to the accessory 20, the device processor 38 uses digital data to audio tone conversion software 40 to create an audio file having varying frequency tones that varied in accordance with the predetermined scheme to form an audio encoded version of the digital data. The audio file is then transferred to the accessory audio input port 26 through the device audio output 32. Audio tone to digital data conversion software 42 is executed by the accessory processor 24 to decode the received audio file into the digital data from which the audio file was created. The digital data can then be used by accessory as needed.
Digital data can be also transferred from the accessory 20 to the device 22 through an infrared encoding scheme. The digital data to be transferred between the accessory 20 and the device 22 is converted into a series of infrared signals by infrared conversion software 46 and 48 residing in the accessory 20 and similar infrared conversion software 54 and 56 residing in the device 22. The infrared signals are transferred between the device 22 and accessory 20 through respective infrared transceivers 50 and 52. Infrared ports are provided on many devices so that the device can receive remote control signals. By repurposing the control codes into infrared signals representing digital data, digital data can be transferred from the accessory 20 to the device 22, or vice versa, without using the device's digital input/output port. In addition, the accessory does not require expensive digital communication circuitry and can be constructed from inexpensive components. For example, an infrared signal corresponding to volume up remote control signal received from the accessory 20 through the device's infrared port 52 can be interpreted as a digital one by infrared conversion software 54 in the device 22 and a volume down control signal can be interpreted as a digital zero. By converting a digital data file to a series of volume up and down controls, the accessory 20 can transfer digital data to a device 22 through the device's existing infrared port. Once the digital data file has been reconstructed by the device, the data can be displayed or executed by the device. By providing the accessory 20 with both audio and infrared encoding circuitry, a single accessory can be created that can be used with a wide variety of different types of devices.
The conversion software for the device is preferably downloaded through a digital data input/output port 44 on the device 22. Since the software is downloaded to the device, an accessory can easily be designed for a pre-existing device that was not designed for use with such an accessory and the functioning of the accessory can be upgraded after its construction and purchase. Alternatively, the conversion software can be installed on the device at the factory if the device is specially designed to be used with an accessory that communicates in the manner specified.
An FM modulator 58 and transmitter 60 may be included in the accessory 20 to enable the accessory to transmit audio from the device 22 to an FM stereo receiver as described more detail herein. The device controls can be used to set the transmission frequency of the modulator and transmitter 60 through the transfer of encoded audio files. In such an embodiment, it is use to be able to use the phone controls to set the frequency of the FM transmitter. A microphone 62 on the accessory can be used to provide the accessory with a voice recording functionality. The audio from the microphone 62 can be transmitted to the device 22 directly as analog audio while control signals for implementing the voice recorder functionality are received as encoded audio files from the device 22. The voice recorded samples can be saved in the device 22 and played on the device's speaker 64. Any data transmitted between the accessory 20 to the device 22 can be encoded at ultrasonic frequencies and superimposed on concurrently transmitted audio files such that the digital data signals can be communicated without noticeably interfering with the use of the audio output.
If digital data needs to be transmitted from the accessory to the device, the method proceeds to step 94 and the accessory's application software converts the digital data into an audio data file of selected frequency tones in step 96. The audio file is then transferred to the device from the accessory through the device's audio output port in step 98. In step 100, the audio data file is converted back into the original digital data with the software in the device. The digital data can then be used to control a device function as shown in step 102 or transferred to an internet service provider by the device as shown in step 104.
Alternatively, the present method for transferring data can be embodied in a printer 180 that prints a file received from a digital music player's audio output 182 as shown in
