DE10021364A1 - Radio signal transmission device for radio communication between basic device and external device, provides packets satisfying mathematical relationships involving packet transmission time and time intervals - Google Patents

Abstract

The radio signal transmitters modulate the data signals of the peripheral device into radio signals with predetermined packets for sending to a main device via a radio signal receiver. The packets satisfy predetermined relationships involving the packet transmission time, the time interval between the corresponding packets within a frame and the time interval between two consecutive packets. The first radio signal transmitters (251-254) modulate the data signals of the peripheral devices (21-24) into a first radio signal which is locked with two copies of first packets in series within a frame. The second radio signal transmitters modulate the data signals of the peripheral devices into a second radio signal which is locked with two copies of second packets in series within the frame. A radio signal receiver (255) is connected to a main device (20) for receiving the first and second radio signals using a common antenna to send the first and second packets to the main device. An Independent claim is also included for a radio signal transmission method.

Description

The present invention relates to signal transmission direction for communicating peripheral devices with a Basic device, and more precisely on a signal transmission device for wireless communication of one or more peripheral Devices over the same frequency channel. The present inven dung also relates to a commu signal transmission method nieren two or more peripheral devices with one Basic device over the same frequency channel.

A basic data processing device, such as a personal computer ter or a game console is becoming increasingly popular these days. With the advanced functions of the basic unit developed various peripheral devices to use with it are. For example, an input device is a person nalcomputers developed from a conventional input key device, such as a keyboard, towards an input device tion that is essential for Windows software, such as a mouse or a touch platform, even to a Joy stick or a gaming platform that ver. for gaming software is applied. These devices are often in front of the basic device present at the same time. Especially for advanced games the use of more than one gaming platform is the same quite common early on. It is therefore conceivable that the com plicated connection between the various peripheral devices and restrict the basic operation of the user becomes.

To solve the above problem and ease of use to improve communication between the peripheral Devices and the basic device through a wireless transmission  executed, the connecting cables are omitted. In infrared (IR) is one of the media that is capable of one perform wireless transmission. An IR device is relatively cheap and easy to manufacture. The use of a However, the IR device has a spatial limitation. If an IR input device is used, one becomes free he transmission path because of the critical directional characteristics stik the IR needed. As a result, communication between the IR input device and the basic device other objects to be disturbed.

Nowadays a radio frequency (RF) device is developed um as another type of medium for wireless over serve to serve. For example, a mouse, a Ta stature, a gaming platform and a joystick wireless with egg personal computer (PC) via a signal transmission device device. The signal transmission device includes four RF transmitters, each on the four input device are attached, and the four RF receivers are each attached to the PC. The input signals from the four input devices are generated wirelessly by the respective RF transmitters to the corresponding RF receivers transfer. Each of the RF transmitters and the RF receivers will controlled by a microcontroller. To be among themselves The frequency channels of the four inputs are not to be disturbed directions for transmitting the respective RF signals the.

From the above description are four transmitters, four receivers and their respective microcontrollers in the conventional Si Signal transmission device included. The numerous Elements lead to high costs and complicated hardware.

Therefore, it is an object of the present invention to Provide signal transmission device that the elements  te integrated at the signal receiving end to reduce costs reduce and simplify hardware.

Another object of the present invention is to provide a To provide signal transmission methods that allow that two or more radio transmitters are equal to one frequency channel use early so that the elements of a signal transmission supply device to be integrated at the signal receiving end to reduce costs and simplify hardware.

A radio signal transmission method for communicating a Variety of peripheral facilities with a main facility The same frequency channel includes the steps transforming a data output from the plurality of peripheral devices in packages; modulating the packets into radio signals, each of the radio signals being a plurality of Includes copies of packages within each frame; on Transfer the radio signals with the packets accordingly correct timing relationships between two packages for each of the radio signals, creating the packets in a way be staggered, which allows at least one of the multiple copies of packages within each frame for each the radio signals are transmitted without a collision; and a Receive and reduce the packets free of one Collision are based on effective data that the basic device be provided.

A carrier is preferably used for each of the radio signals frequency between a packet transmission frequency and a Blind frequency for a packet transmission section or Transmission section without a packet switched to interference to avoid.

The data packets preferably add preamble for identification bel bytes and a checksum. If a data packet on the  Receiving end is received, the effectiveness of the received determined package by checking the checksum, and the Origin of the received packet is checked by checking the Preamble bytes determined.

In one embodiment, which includes two peripheral devices, the radio signal from the first peripheral device includes two copies of the first packet within each frame and the radio signal from the second peripheral device includes two copies of the second packet within each frame. The predetermined timing relationships include:

G1 <P

G2 <2P + G1 <3P

G3 <2P + G2 <5P

in which
P is a packet transmission time for each of the first packets and the second packets;
G1 is a time interval between the first packets within the same frame;
G2 is a time interval between the second packets within the same frame; and
G3 is a time interval between two successive first packets each in two successive frames.

Accordingly, a frame length is greater than 8 times P.

The radio signals are preferably high-frequency (RF) signals.

A radio signal transmission device for communicating a first peripheral device and a second peripheral device with a main device according to the present invention includes first and second radio signal transmitters used for the first and second peripheral devices, respectively, and some radio signal receivers. The first radio signal transmitter is electrically connected to the first peripheral device for modulating a data output from the first peripheral device into a first radio signal and for transmitting the first radio signal, the first radio signal including two copies of the first packets in series within each frame. The second radio signal transmitter is electrically connected to the second peripheral device for modulating a data output from the second peripheral device into a second radio signal and for transmitting the second radio signal, the second radio signal including two copies of the second packets in series within each frame. The radio signal receiver is electrically connected to the main device for receiving the first and second radio signals with a common antenna and for transmitting the first and second packets to the main device. The transmission of the first and second packets meet the following conditions:

G1 <P

G2 <2P + G1 <3P

G3 <2P + G2 <5P

in which
P is a packet transmission time for each of the first packets and the second packets;
G1 is a time interval between the first packets within the same frame;
G2 is a time interval between the second packets within the same frame; and
G3 is a time interval between two successive first packets each in two successive frames.

The first radio signal transmitter preferably closes a microphone controller, a modulator and a transmitting antenna. The Wed krocontroller is electrical with the first peripheral on direction to transform the data output from the first  peripheral device in the first packets and for sending a carrier frequency setting signal connected. The modulator is electrical with the microcontroller to provide a Carrier for the first packets and for switching a frequency of the carrier between a packet transmission frequency and a Reactive frequency in response to the carrier frequency Setting signal connected. The transmission antenna is electrical with connected to the modulator for transmitting the first radio signal.

The modulator preferably includes a synthesizer and egg a controlled oscillator. The synthesizer is electrical connected to the microcontroller to get frequency data of the Trä to load and store in it chern, and by an enable signal that in the carrier fre sequence setting signal is included to be triggered, to generate a control signal that corresponds to a frequency level of the Displays wearer. The controlled oscillator, which is a voltage controlled oscillator is electrical with the Mi krocontroller and the synthesizer for switching the frequency of the carrier between the packet transmission frequency and the Reactive frequency in response to the control signal and for charging of the packets onto the carrier at the packet transmission frequency connected.

Preferably, the synthesizer with the frequency data of the Carrier frequency setting signal loaded while the span voltage controlled oscillator to the packet transmission frequency or sets the reactive frequency.

In general, the second radio signal transmitter has the same Structure like the first radio signal transmitter, and both transmitters are operated via radio frequency (RF) signals.

The radio signal receiver preferably connects to a reception tenne, a demodulator and a microcontroller. The  Receiving antenna is used to receive the first and / or the second radio signal used. The demodulator becomes electrical with the receiving antenna for demodulating the carrier at the Packet transmission frequency connected to the first and / or to realize the second packages. The microcontroller is electrically with the main device and the demodulator for Filtering the first and / or the second packets connected to transfer effective data to the main facility.

For example, the radio signal transmission device can be ge according to the present invention, so that a Keyboard, mouse, joystick and / or game board form communicates with a personal computer. The funksi Signal transmission device according to the present invention can also be applied to a variety of games platforms communicated with a game console.

The present invention can best be accomplished by the following Description with reference to the accompanying drawings be understood. The drawings show:

Fig. 1 is a block diagram schematically showing a structure of a signal transmission device according to the present invention;

FIGS. 2A-2F are waveform diagrams, each of the relative phase of the frame sequence shown in the first transmitter to the phase of the frame sequence in the second transmitter;

Fig. 3 is a schematic block diagram showing a preferred embodiment of a radio signal transmitter according to the present invention; and

Fig. 4 is a schematic block diagram showing a preferred embodiment of a radio signal receiver according to the present invention.

The present invention will now become more specific with reference be described in the following embodiments. It should be noted that the following descriptions of preferred embodiments of this invention herein only presented for purposes of illustration and description become; it is not intended to be exhaustive or limited to the precise training disclosed his.

Please refer to FIG. 1, which is a block diagram schematically showing a structure of a signal transmission device according to the present invention. The signal transmission device 25 is used so that four peripheral devices 21 , 22 , 23 and 24 communicate with a main device 20 . The peripheral of the four devices 21, 22, 23 and 24 to the main device 20 selectively constricting übertra data is modulated into radio signals including data packets through their respective radio signal transmitter 251, 252, 253 and 254th The signals transmitted by the various peripheral devices are received by a common radio signal receiver 255 and then demodulated in order to implement the data for the main device 20 . Compared to the conventional signal transmission device mentioned above, three radio signal receivers and their respective microcontroller are omitted.

Under the above hardware structure, an asynchronous time empire multiple access (A-TDMA) technology applied to it allow two or more radio signals over the same Carrier channel are transmitted. However, it should be pointed out sen that if there is no direct connection between the transmitters  stands for the data transmission for the sake of lower costs synchronize the carriers of the transmitters with each other more or have fewer phase differences. To disrupt the Radio signals that are transmitted in the same frequency channel to avoid the data packets among themselves piert and transmitted in frames, and the time intervals between There are two packets for each radio signal applies to stagger the transmission times of the packets. In this way it can be ensured that at least one Copy the packets within each frame for each radio signal arrives at the receiver regardless of the phase differences.

The transmission timings of the packets according to the present invention will be described below, and examples will be given with reference to Figs. 2A-2F to illustrate the various data transmission situations of an RF mode transmitter for communicating a first peripheral device and one to illustrate a second peripheral device with a main device. FIGS. 2A-2F are waveform diagrams, each of these shows the relative phase of the frame sequence in the first transmitter to the phase of the frame sequence in the second transmitter. As shown in the figures, the first and the second radio signals T1 and T2 can be intentionally or randomly synchronized or have more or less phase differences with one another.

For the RF mode transmitter, the first radio signal T1 sent from the first transmitter to communicate the first peripheral device with the main device includes two copies of the first packet P1 in series within each frame F, and the second radio signal T2 , which is sent from the second transmitter for communicating the second peripheral device with the main device, also two copies of the second packets P2 in series in the same frame unit F as above. In addition, the transmission of the first and second packets P1 and P2 fulfills the following conditions:

G1 <P

G2 <2P + G1 <3P

G3 <2P + G2 <5P

in which
P is a packet transmission time for each of the first packets P1 and the second packets P2;
G1 is a time interval between the first two packets P1 within the same frame F;
G2 is a time interval between the two second packets P2 within the same frame F; and
G3 is a time interval between two successive first packets P1 each in two successive frames F.

In view of the timing relationships above, it is guaranteed that at least one packet will be transmitted from each transmitter within each frame to the receiver without collision, as shown in Figs. 2A-2F.

The hardware for performing the above A-TDMA procedure is are illustrated below.

Please refer to Figure 3, which is a schematic block diagram that is a preferred embodiment of a radio signal transmitter of the present invention. The radio signal transmitter includes a microcontroller 41 , a modulator 42 and a transmission antenna 43 . The microcontroller 41 is electrically connected to a peripheral device (not shown) for receiving data from the peripheral device which transforms the data into packets, each consisting of preamble bytes, data and a checksum, and for transmitting a carrier frequency setting signal 51 . The modulator 42 includes a synthesizer 421 , a voltage controlled oscillator 422 , a mixer 423 and an amplifier 424 . After it has been loaded with the transmission frequency data of the carrier frequency setting signal 51 from the microcontroller 41 , the synthesizer 421 is triggered by an enable signal 52 , which is included in the signal 51 , in order to generate a control signal 53 . The voltage controlled oscillator 422 switches the carrier frequency between a transmit frequency and a reactive frequency in response to the control signal 53 . While the transmission frequency is that which is used for a packet transmission and is applied during the packet period "P", the reactive frequency is applied during the waiting periods G1, G2 and G3. The frequency is changed to avoid interference. Thereafter, the packets P1 and P2 are loaded into the carrier C of the transmission frequency in the mixer 423 to form a radio signal T1 or T2, which is amplified in the amplifier 424 , and then the radio signal T1 or T2 is transmitted by the antenna 43 .

Please refer to FIG. 4, which is a schematic block diagram showing a preferred embodiment of the radio signal receiver according to the present invention. The radio signal receiver includes an antenna 51 , an amplifier 52 , a demodulator 53 and a microcontroller 54 . The radio signals from all peripheral devices are received by antenna 51 and amplified by amplifier 52 . Demodulator 53 demodulates the radio signals to isolate the packets. The packets are then filtered by microcontroller 54 to realize the effective data provided to the main facility. Because each of the packets includes preamble bytes, data and a checksum, these sections can be used to identify the packet received. For example, if a packet ever collided with another packet, the checksum of the received packet will not pass the microcontroller 54 check and the packet will be ignored. If the packet is confirmed to be complete in checksum, the preamble bytes can tell the origin of the packet and whether or not the packet is received in a duplicate.

This embodiment of a radio signal transmission device, which is illustrated with reference to FIGS. 3 and 4, is particularly suitable to be used with a game console with two game platforms.

Although the timing relationships mentioned above allow it, that at least one packet from each transmitter within each frame is sent to the common recipient, the Frame length can be optimized to the transmission rate to maxi lubricate. For example, each duration P does not only close that Time during which the packet is transmitted, but also the time required for the synthesizer set, and for any tasks that the transmitter cause it to stay on the broadcast frequency. Deswe to the time used for the transmission frequency minimize the actions of the synthesizer and the tension controlled oscillators can be set so that they easily overlap. For example, if the voltage controlled Oscillator the carrier frequency from the transmit frequency to the Reactive frequency or from the reactive frequency to the transmission frequency switches in response to the control signal, a period of time needed to determine the carrier frequency at the transmit frequency or the Stabilize reactive frequency. During the stabilization pe The synthesizer can riod with the frequency data of the carrier frequency setting signal can be loaded in advance. This has the synthesizer loads the frequency data of the transmission frequency, while the voltage controlled oscillator is on the blind frequency or vice versa, so that the duration P and the Total transmission time can be minimized.  

On the other hand, the length of a frame is 2.G2 + 2.P = 2.P + G1 + G3, both of which must be greater than 8.P due to the timing relationships above. In other words, the frame length should be at least 8 times the duration of a packet. Accordingly, an embodiment is given as follows.

• - Bit rate of each transmitter = 62.5 kbps
• - Bit time = 16 µsec
• - Preamble bytes = 3 bytes
• - Data = 6 bytes
• - Checksum = 1 byte
• - P = 1.4 ms
• - G1 = 1.5 ms
• - G2 = 4.5 ms
• - G3 = 7.5 ms
• - frame = 11.8 ms.

To summarize: by the signal transmission method and the device used according to the present invention data from two or more radio transmitters from received by a single receiver in the same frequency channel be. As a result, the cost can be reduced, and the hardware can be integrated.

Claims (22)

A radio signal transmission device ( 25 ) for communicating a first peripheral device ( 21 , 22 , 23 , 24 ) and a second peripheral device ( 21 , 22 , 23 , 24 ) with a main device ( 20 ), comprising:
a first radio signal transmitter ( 251 , 252 , 253 , 254 ) electrically connected to the first peripheral device ( 21 , 22 , 23 , 24 ) for modulating a data output from the first peripheral device ( 21 , 22 , 23 , 24 ) into a first one Radio signal (T1) and connected to transmit the first radio signal (T1), the first radio signal (T1) including two copies of first packets (P1) in series within each frame (F);
a second radio signal transmitter ( 251 , 252 , 254 , 254 ) which is electrically connected to the second peripheral device ( 21 , 22 , 23 , 24 ) for modulating a data output from the second peripheral device ( 21 , 22 , 23 , 24 ) into a second one Radio signal (T2) and for transmitting the second radio signal (T2) is connected, the second radio signal including two copies of second packets (P2) in series within each frame (F); and
a radio signal receiver ( 255 ), which is electrically connected to the main device ( 20 ) for receiving the first and second radio signals (T1, T2) with a common antenna ( 51 ) and for transmitting the first and second packets (P1, P2) to the main device ( 20 ) is connected;
the transmission of the first and second packets (P1, P2) fulfilling the following conditions:
G1 <P
G2 <2P + G1 <3P
G3 <2P + G2 <5P
in which
P is the packet transmission time for each of the first packets (P1) and the second packets (P2);
G1 is a time interval between the first packets (P1) within the same frame (F);
G2 is a time interval between the second packets (P2) within the same frame (F); and
G3 is a time interval between two successive first packets (P1) each in two successive frames (F). 2. Radio signal transmission device ( 25 ) according to claim 1, characterized in that the first radio signal transmitter ( 251 , 252 , 253 , 254 ) includes:
a microcontroller 41 , which is electrically connected to the first peripheral device ( 21 , 22 , 23 , 24 ) for transforming the data output from the first peripheral device ( 21 , 22 , 23 , 24 ) into the first packets (P1) and for the outside one Carrier frequency setting signal (S1) is connected;
a modulator ( 42 ) electrically with the microcontroller ( 41 ) for providing a carrier (C) for the most packets (P1) and for switching a frequency of the carrier (C) between a packet transmission frequency and a reactive frequency is connected to the carrier frequency setting signal (S1); and
a transmission antenna ( 43 ) which is electrically connected to the modulator ( 42 ) for transmitting the first radio signal (T1). 3. Radio signal transmission device ( 25 ) according to claim 2, characterized in that the modulator includes:
a synthesizer ( 421 ) which is electrically connected to the microcontroller ( 41 ) for loading with frequency data of the carrier frequency setting signal (S1) and for storing the same, and is triggered by an enable signal (S2) which is in the carrier frequency Setting signal (S1) is included to generate a control signal (S3) indicating a frequency level of the carrier (C); and
a controlled oscillator ( 422 ) which is electrically connected to the microcontroller ( 41 ) and the synthesizer ( 421 ) for switching the frequency of the carrier (C) between the packet transmission frequency and the reactive frequency in response to the control signal (S3) and for loading the Packets connected to the carrier (C) at the packet transmission frequency. 4. Radio signal transmission device ( 25 ) according to claim 3, characterized in that the controlled oscillator ( 422 ) is a voltage-controlled oscillator. 5. Radio signal transmission device ( 25 ) according to claim 1, characterized in that the second radio signal transmitter ( 251 , 252 , 253 , 254 ) includes:
a microcontroller ( 41 ) electrically connected to the second peripheral device ( 21 , 22 , 23 , 24 ) for transforming the data output from the second peripheral device ( 21 , 22 , 23 , 24 ) into the second packets (P2) and out sending a carrier frequency setting signal (S1) is connected;
a modulator ( 42 ) electrically with the microcontroller ( 41 ) for providing a carrier (C) for the two packets (P2) and for switching a frequency of the carrier (C) between a packet transmission frequency and a reactive frequency in response is connected to the carrier frequency setting signal (S1); and
a transmission antenna ( 43 ) which is electrically connected to the modulator for transmitting the second radio signal (T2). 6. Radio signal transmission device ( 25 ) according to claim 5, characterized in that the modulator ( 42 ) includes:
a synthesizer ( 421 ) which is electrically connected to the microcontroller ( 41 ) for loading with frequency data of the carrier frequency setting signal (S1) and for storing the same, and is triggered by an enable signal (S2) which is in the carrier frequency Setting signal is included to generate a control signal (S3) indicating a frequency level of the carrier (C); and
a control oscillator ( 422 ) electrically with the microcontroller ( 41 ) and the synthesizer ( 421 ) for switching the frequency of the carrier (C) between the packet transmission frequency and the reactive frequency in response to the control signal (S3) and for loading the packets is connected to the carrier (C) at the packet transmission frequency. 7. Radio signal transmission device ( 25 ) according to claim 6, characterized in that the controlled oscillator ( 422 ) is a voltage-controlled oscillator. 8. Radio signal transmission device ( 25 ) according to claim 7, characterized in that the synthesizer ( 421 ) with the frequency data of the carrier frequency setting signal (S1) is loaded ge, while the voltage-controlled oscillator ( 422 ) adjusts to the packet transmission frequency or the reactive frequency. 9. radio signal transmission device ( 25 ) according to claim 1, characterized in that the radio signal receiver ( 255 ) includes:
a receiving antenna ( 51 ) for receiving the first and / or the second radio signals (T1, T2);
a demodulator ( 53 ), electrically connected to the receiving antenna, for demodulating the carrier (C) at the packet transmission frequency to realize the first and / or the second packets (P1, P2); and
a microcontroller ( 54 ), electrically connected to the main device ( 20 ) and the demodulator ( 53 ), for filtering the first and / or the second packets (P1, P2) in order to effectively send data to the main device ( 20 ) transfer. 10. Radio signal transmission device ( 25 ) according to claim 1, characterized in that the main device ( 20 ) is a personal computer and each of the first and second peripheral devices ( 21 , 22 , 23 , 24 ) is selected from a group consisting of a keyboard , a mouse, a joystick and a gaming platform. 11. Radio signal transmission device ( 25 ) according to claim 1, characterized in that the main device ( 20 ) is a game console and the first and second peripheral devices ( 21 , 22 , 23 , 24 ) are two game platforms. 12. Radio signal transmission device ( 25 ) according to claim 1, characterized in that the first and the second radio signals (T1, T2) are radio frequency (RF) signals. 13. A radio signal transmission method for communicating a plurality of peripheral devices ( 21 , 22 , 23 , 24 ) with a main device ( 20 ) over the same frequency channel, comprising the following steps:
Transforming a data output from the plurality of peripheral devices ( 21 , 22 , 23 , 24 ) into packets (P1, P2);
Modulating the packets (P1, P2) into radio signals (T1, T2), each of the radio signals (T1, T2) including a plurality of copies of packets (P1, P2) within each frame (F);
Transmitting the radio signals (T1, T2) with the packets (P1, P2) according to predetermined timing relationships between two packets (P1, P2) for each of the radio signals (T1, T2), thereby causing the packets (P1, P2) in a manner staggered, which allows at least one of the plurality of copies of packets (P1, P2) within each frame (F) for each of the radio signals (T1, T2) to be sent without collision; and
Receiving and reducing the packets (P1, P2) that are free of collision to effective data that are provided to the main device ( 20 ). 14. Radio signal transmission method according to claim 13, characterized characterized in that for each of the radio signals (T1, T2) ei ne carrier frequency between a packet transmission frequency and a reactive frequency for a packet transmission cut or a transmission section without a package is switched to avoid interference. 15. Radio signal transmission method according to claim 13, characterized characterized in that the data is transformed into packets by adding preamble bytes and a checksum for identifi cation can be added. 16. A radio signal transmission method according to claim 15, further comprising a step of determining whether the received Package is effective by checking the checksum. 17. A radio signal transmission method according to claim 16, further comprising a step of determining the origin of the effective received packet by checking the preamble bel bytes. 18. Radio signal transmission method according to claim 13, characterized in that the plurality of peripheral devices ( 21 , 22 , 23 , 24 ) includes a first and a second peripheral device. 19. Radio signal transmission method according to claim 18, characterized in that the radio signal (T1) from the first pe riphereneinrichtung ( 21 , 22 , 23 , 24 ) includes two copies of the most packets (P1) within each frame (F) and that Radio signal (T2) from the second peripheral device ( 21 , 22 , 23 , 24 ) includes two copies of the second packet (P2) within each frame (F). 20. A radio signal transmission method according to claim 19, characterized in that the predetermined timing relationships include:
G1 <P
G2 <2P + G1 <3P
G3 <2P + G2 <5P
in which
P is a packet transmission time for each of the first packets (P1) and the second packets (P2);
G1 is a time interval between the first packets (P1) within the same frame (F);
G2 is a time interval between the second packets (P2) within the same frame (F); and
G3 is a time interval between two successive first packets (P1) each in two successive frames (F). 21. Radio signal transmission method according to claim 20, characterized characterized in that a frame length greater than 8 times P is. 22. Radio signal transmission method according to claim 13, characterized characterized in that the radio signals (T1, T2) radio frequency (RF) signals are.