Classifications

• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04W—WIRELESS COMMUNICATION NETWORKS
  • H04W88/00—Devices specially adapted for wireless communication networks, e.g. terminals, base stations or access point devices
  • H04W88/02—Terminal devices
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04M—TELEPHONIC COMMUNICATION
  • H04M1/00—Substation equipment, e.g. for use by subscribers
  • H04M1/72—Mobile telephones; Cordless telephones, i.e. devices for establishing wireless links to base stations without route selection
  • H04M1/725—Cordless telephones
  • H04M1/72502—Cordless telephones with one base station connected to a single line
  • H04M1/72505—Radio link set-up procedures
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04M—TELEPHONIC COMMUNICATION
  • H04M1/00—Substation equipment, e.g. for use by subscribers
  • H04M1/72—Mobile telephones; Cordless telephones, i.e. devices for establishing wireless links to base stations without route selection
  • H04M1/725—Cordless telephones
  • H04M1/72502—Cordless telephones with one base station connected to a single line
  • H04M1/72505—Radio link set-up procedures
  • H04M1/72513—On hold, intercom or transfer communication modes

Definitions

• This invention relates generally to communication systems and more specifically to the field of cordless telephone systems.
• Portable telephone systems such as second-generation digital cordless telephone (CT2) systems, typically include multiple call point stations each providing multiple RF channels. These call point stations also being referred to as telepoints or cordless fixed parts (CFPs). CFPs allow persons using portable telephone handsets (also known as cordless portable parts, CPPs), to access the public switched telephone network (PSTN). Access to the PSTN can occur when a CPP gets in range of a telepoint (CFP) and after the CPP (handset) has established a synchronous link with the CFP (base station).
• CFP public switched telephone network
• a handset initiating a call to a base station asynchronously transmits on one available channel of the handset's transceiver, which corresponds to a radio frequency (RF) channel in the base station (each base station being capable of supporting up to 40 channels).
• RF radio frequency
• the communication protocol standard includes four main burst structures, called multiplex 3 (MUX 3), multiplex 2 (MUX 2) and multiplex 1 (MUX 1) which is further sub- divided into either multiplex 1.4 or 1.2 (MUX 1.4 or MUX 1.2).
• MUX 3 is utilized mainly for communication link initiation (link establishment and re-establishment) from a CPP to a CFP.
• MUX 2 is used primarily for communication link establishment and for link initiation from the base station(CFP).
• the MUX 1 burst structures (MUX 1.2 and MUX 1.4) are used primarily for voice/data communications, signaling information, and control messages from the CPP (portable) and CFP (base).
• the matrix 100 shows the link setup direction, the message direction, MUX mode, and the content of the link identification code (LED) for each handshake sequence.
• the LID code is used for the following: i). End point identification for CPP (handset) call setup; ⁇ ). Link reference for associating CPP (handset) and CFP (base) calls during handshake exchanges and link re-establishments; and for iii). Base identifier (BID), which is the ringing address to which one or more CPP's will respond to.
• BID Base identifier
• Row 102 shows a basic sequence on how a handset (CPP) establishes communications with a telepoint (CFP), row 104 shows how a telepoint station establishes communications with a handset, and row 106 shows how a communication link is re-established in case the link is disrupted during an ongoing communication session.
• CCP handset
• CCP base station
• MUX 3 message including the identification number of the handset (end point ID).
• MUX 2 a message with the LID having the communication link reference identification number which informs the handset that the link has been granted.
• the units go to the MUX 2 protocol where the CFP transmits a supervisory message and acknowledgment.
• the capabilities of both the CPP and CFP are determined, and authorization to use the system is determined by the CFP.
• the two units then move on to the MUX 1 protocol by a request from the CFP and an acknowledgment by the CPP.
• dial tone is sent out by the CFP, the CPP then dials the telephone number he wishes to access.
• a voice communication link being established between the CPP and the party at the dialed number telephone number.
• the voice messages are either transmitted using MUX 1.2 or MUX 1.4 format depending on the specific system 100 being utilized.
• CPPs are only capable of communicating with CFPs, although as also mentioned before, either device can initiate a call to the other.
• CT2 systems become more widely used, a need thus exists for a way of allowing for CPPs to communicate directly with other CPPs without having to go through a CFP. It would also be desirable to be able to achieve this goal while still operating under the CT2 communication protocol standard. This providing for added capabilities and benefits to CT2 handset users.
• FIG. 1 shows a matrix of the prior art handshake sequence between the cordless telephone device (CPP) and the telepoint base station (CFP).
• CCP cordless telephone device
• CCP cordless telephone device
• CCP cordless telephone device
• CCP telepoint base station
• FIG. 2 shows a diagram of a typical CT2 system in accordance with the present invention.
• FIG. 3 is a diagram showing the CPP to CPP registration process in accordance with the present invention.
• FIG. 4 shows a diagram of a CPP to CPP link establishment in accordance with the present invention.
• FIG. 5 is a block diagram of a cordless telephone in accordance with the present invention.
• Cordless telephone system 200 is preferably a second generation cordless telephone system, better known as a CT2 system.
• Cordless telephone system 200 comprises one or more base stations (CFPs) 204 and 208, and one or more handsets (CPPs) 210, 212, 214 and 216.
• CFPs base stations
• CPPs handsets
• PSTN public switched telephone network
• the base station sets up the communication link between the requesting handset and the PSTN 210, thereby allowing a handset user to make a standard telephone call to a land-line party.
• base station 204 is shown to have a typical operating range shown by communication coverage area 202, while base station 208 has a coverage area 206.
• Handsets are typical very low power portable communication units having a maximum output power rating in the order of 10 milli-watts (mW).
• Each base station or telepoint 204 and 208 can support up to a maximum of 40 communication channels.
• the handset Upon requesting access to a base station, the handset will scan the base station's RF channels in order to get an available channel (e.g., a channel which is not busy). At which point the handset transmits a link request in MUX 3 which the base station can grant using a MUX 2 return transmission. This is followed by a MUX 2 handshake between the two units and a handset ID check, in order to establish the identification of the particular handset that is originating the call. The handset ID is used for both billing purposes and to ensure that only authorized units are using the system.
• the calling handset emulates a base station MUX 2 poll message using a BED (base identification number) in the LID field and the called handset PID
• a handset with this feature may establish a direct link with any CT2 Common Air interface (CAI) compatible handset (CPP).
• CAI Common Air interface
• a registration process 300 in accordance with the present invention is shown.
• the registration process is a set-up process which enables a particular set of handsets to talk with each other directly.
• handsets featuring handset to handset communication capability (CCC) in accordance with the present invention contain multiple registration slots and a random Base Identity Code (BID) which identifies a particular handset to other handsets registered to receive calls from it.
• BID Base Identity Code
• the handset-to-handset capable handset may contain separately portioned registration slots for incoming handset calls which may be enabled and disabled at the users discretion, thereby blocking unwanted handsets from establishing access with the particular handset.
• CT2 handsets are usually sold via retail outlets, the registration process as shown in FIG.
• the registration information e.g., ID's of handsets which can communicate directly with a particular handset, etc.
• ID's of handsets which can communicate directly with a particular handset, etc. could be programmed into each radio either at a service shop or during the manufacturing process.
• the registration process is bi-directional if both handsets are capable of handset-to-hanset communications (either handset can initiate a call to the other) and unidirectional if only one handset is handset-to-handset capable (e.g., in this particular case, only the CCC capable handset would be able to initiate the call).
• the over the air registration step is executed by the portable handset (CPP2) initiating a MUX 3 link request 302 in which the handset identity code (HIC) and the manufacturer identity code (MIC) equals the CPP2 portable identification code (PID).
• the link identification code (LED) for over the air registration is set equal to "FFFF”.
• the channel marker bit pattern (CHMP) is also sent in this transmission.
• the receiving handset, CPPl at the same time is scanning the available radio frequency channels in MUX 3 for a LID equal to "FFFF". Once CPPl receives the LID, the units begin communicating in MUX 2, as shown in step 304.
• a link grant message 306 is then sent by CPPl, the message includes CPP2's PID and the LID, the SYNCF (synchronization word from CFP), set equal to the link reference identification number.
• CPP2 sends an identification received message ("ID-OK") which includes CPP2's P D and the SYNCP (synchronization word from CPP).
• CPP2 in step 308 then sends a layer two link protocol initialization command which is referred to as a Set Asynchronous Balanced Mode message ("SABM") to CPPl. This in turn is followed by CPPl acknowledging the SABM message in step 310. Steps 308 and 310 also reset all of the state variables
• CPP2 sends a set asynchronous Balanced mode (SABM) message to CPPl.
• SABM is a layer two link protocol initialization command This is followed by a SABM acknowledgment message from CPPl to CPP2.
• CPP2 informs CPPl of its capabilities (TERM_CAP, terminal capabilities) including information on any activated features via element "FA”.
• CPP2 informs CPPl of its manufacturer's identity code (MANIC) and the manufacturers CPP model identity code (MODEL).
• MANIC manufacturer's identity code
• MODEL manufacturers CPP model identity code
• CPPl then informs CPP2 of its capabilities (BAS_CAP, base capabilities since CPPl in the present invention is emulating a base station) in step 328.
• CPPl sends a message informin CPP2 of its BED and PID, and that it is capable of CPP-CPP registration.
• CPP2 then acknowledges receipt of the information in step 316.
• CPPl then transmits an On Air Registration Acknowledgment (OARA) in step 318, and in step 320, CPP2 acknowledges receipt of the OARA.
• OARA On Air Registration Acknowledgment
• CPP2 stores CPPl' s BID allowing for incoming calls from CPPl, while in step 320 CPPl stores CPP2's PID in the assigned registration slot.
• step 322 CPPl transmits the initialization information element (ENTT), and in step 324, CPP2 acknowledges receipt of the INIT. At this point the registration of CPPl and CPP2 is complete, thereby allowing for the two handsets to be able to communicate directly with each other, whenever they so chose.
• INIT initialization information element
• Link establishment protocol diagram 400 begins with CPPl selecting the CPP2 registration slot previously established in the registration process. Once the CPPl user presses the proper key entry in CPPl's keypad requesting to establish a communication link with CPP2, the CPPl handset in step 402 transmits a poll message in MUX 2. If the poll message is successfully received by CPP2, CPP2 transmits a response to the poll which is also transmitted in MUX 2. This is followed by both units interchanging handshake ID-OK code words in steps 404 and 406.
• a ring signal message is then sent in step 408.
• the ring signal message can include parameters which can inform CPP2 to ring in a distinct fashion which can inform CPP2 that the transmission is originating from a handset and not a telepoint.
• steps 410 and 412 the two handsets interchange handshake ID-OK messages.
• CPPl in step 414 transmitting a message informing the ringer circuit in CPP2 to shut off.
• Steps 404 through 414 are repeated in order to generate a particular ring cadence (duty cycle).
• Link_request is a request by CPP2 to seize a communication link.
• CPPl receives the request and in step 416, transmits a link grant message. In this message, CPPl sends a CFP acknowledgment assigning a call reference identification number.
• CPP2 responds in step 418, by transmitting an identification-ok message, followed by a layer two link protocol initialization command (SABM), in step 422.
• SABM layer two link protocol initialization command
• CPPl then acknowledges this command in step 424. Once the initialization command has been acknowledged, the communication link between the two handsets has been established.
• steps 422 and 424 initialize all state variables (V(s) and V(r) to zero in order to keep the communication between the two units in synchronization.
• the CPP2 unit then transmits a message informing CPPl of its capabilities in step 426.
• a ring termination message is sent to CPP2 which causes the ringing in CPP2 to turn off completely.
• CPPl follows this message with a message informing CPP2 of its own capabilities in step 430.
• the channel control message (CC) is then transmitted in MUX 2, in step 432.
• CPP2 in step 434 acknowledges the channel control message in MUX 1.
• Another channel control message is sent out by CPPl in step 436, this time using the MUX 1 protocol.
• CPP2 also acknowledges this message using the MUX 1 protocol in step 438.
• the units are connected to the B channel which is a 32 kilobit per second (kbit s) speech or data channel which is then used by the units to transmit their data or voice conversation.
• the units maintain this bi-directional MUX 1 transmission until one of the units decides to hang-up from the conversation. At which point a conventional hang-up routine is followed, which releases the B channel and returns the units to their stand-by states.
• the CPP standby operation is not modified for CCC capability as the CCC poll is received in MUX 2 (step 402). Additionally, BID collisions with CFPs are avoided since CFPs monitor for only MUX 3 link requests, this eliminating outgoing CCC collisions.
• CPPs having CCC capability in this particular case CPPl
• monitor for only MUX 2 polls except for registration and link re-establishment
• CCC link re-establishment is identical to a CPP-CFP link were the CPP that initiates the call emulates a CFP and scans for the called CPP MUX 3 link request during re-establishment.
• the initiating handset emulates a CFP (base station) in order to establish a communication link with the second handset (CPP2).
• the emulation of a CFP by CPPl includes CPPl being the synchronization master for frame, burst and bit synchronization.
• CPP2 will synchronize its frame, burst and bit clocks to the signals received from CPPl.
• CPPl transmits its link establishment poll (402) in MUX 2, as compared to the standard CPP to CFP link establishment were the CPP transmits the Poll in MUX 3. This allows for other CPPs which are usually scanning in MUX 2 under the CT2 protocol to be able to receive the MUX 2 poll without modifying their standard mode of operation.
• the emulation of a CFP by CPPl as discussed above includes CPPl emulating some the base station's communication protocol parameters as established by the CT2 common air interface standard (CAI), such as transmitting a link establishment poll in MUX2, being the timing master and other CFP emulation as shown in FIG. 3 and 4. Also, the registration process shown in FIG.3, of CPPl scanning for a link request (step 302 ) in MUX 3, is also an emulation of a CFP by CPPl, given that CPPs normally do no not scan in MUX 3.
• CAI common air interface standard
• FIG. 5 a simplified block diagram of a radio such as a cordless telephone 500 in accordance with the present invention is shown.
• Cordless telephone 500 comprises a well known RF transceiver 502 for transmitting and receiving RF communication signals via an antenna 504.
• CT2 handsets operate in accordance with the previously mentioned "MPT1375 Common Air Interface Specification" (CAI) which establishes a time-division multiplexed protocol having alternating one millisecond receive and transmit frames separated by guard time segments.
• CAI Common Air Interface Specification
• each transmit/receive segment includes a B channel (64 bits) and a D channel which contains 1 or 2 bits at each end of the B channel.
• a time division multiplexer (TDD) 506 is coupled to transceiver 502 for providing time-division multiplexing and receive/transmit framing of the digital signals.
• An ADPCM CODEC 508 receives voice signals generated by a microphone 510 and processes them for transmission.
• the APCM/CODEC 508 also provides voice signals to be rendered audible via a speaker 512.
• a control means such as controller 514 which is programmed in a known manner except for the modifications to obtain the present invention's capabilities, provides operational control for the cordless telephone 500.
• Controller 514 can be any one of a number of microprocessors or microcontrollers, the controller preferably having input/output capabilities and built-in memory. Controller 514 executes the program which modifies the operation of cordless telephone 500 whenever telephone 500 needs to communicate directly with another cordless telephone. Controller 514 automatically modifies such communication protocol parameters as; which MUX level to use, what information packets to send, as well as other parameters which are required for telephone 500 to emulate in order for it to be able to communicate directly with other telephones, while still allowing telephone 500 to maintain compliance with the CT2 communication protocol standard (CAI).
• CAI CT2 communication protocol standard
• controller 514 modifies the operation of telephone 500 to transmit a link establishment message (as shown in step 402) which substantially emulates a message transmitted by a telepoint, in order for telephone 500 to be able to communicate directly with another telephone.
• Controller 514 also allows telephone 500 to register with another telephone by emulating a base station in the area of scanning in MUX 3 for a link request message (as shown in step 302 in FIG. 3) which is something a CT2 telephone does not perform.
• a subscriber interacts with the cordless telephone via a keypad 516.
• Keypad 516 allows the device user to enable operational features of the telephone 500 such as CCC (handset-to-handset communications) as taught by the present invention.
• a display 520 provides visual interaction for the subscriber.
• a memory block 522 such as an electrically erasable programmable read-only memory (EEPROM), provides storage of the handset's ED number and other important information. Memory block 522 can also include a RAM portion for the temporary storage of information.
• EEPROM electrically erasable programmable read-only memory
• the present invention extends CT2 handset functionality to allow for communications directly between handsets without the RF link passing through a CFP, while at the same time maintaining full compliance with the CT2 Common Air Interface (CAI) protocol standard.
• CAI Common Air Interface
• the calling CPP emulates a CFP MUX 2 poll with a BID in the LID field and the called CPP PED in the HIC and MIC fields.
• the poll is then sent out optionally with a unique ring cadence so that the called CPP user is aware that the incoming call is from a handset.
• the CPP initiating the call continues to emulate a CFP throughout the call.
• a handset with this feature may establish a direct link with any CT2 CAI compatible handset.
• the present invention allows for a cordless telephone handset which operates using the CT2 standard common air interface standard to be able to communicate with another handset directly without disturbing the CT2 communication standard in any fashion.
• the present invention also allows for a more flexible communication system since handset users can not only link up to the PSTN but to other handset users directly.

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• Engineering & Computer Science (AREA)
• Computer Networks & Wireless Communication (AREA)
• Signal Processing (AREA)
• Mobile Radio Communication Systems (AREA)
• Communication Control (AREA)

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• 1993
  • 1993-06-28 TW TW082105131A patent/TW239910B/zh active
  • 1993-07-26 MX MX9304484A patent/MX9304484A/es unknown
  • 1993-07-27 CA CA002121239A patent/CA2121239A1/en not_active Abandoned
  • 1993-07-27 WO PCT/US1993/007029 patent/WO1994005101A1/en not_active Application Discontinuation
  • 1993-07-27 EP EP93918403A patent/EP0609422A4/de not_active Withdrawn
  • 1993-07-27 JP JP6506279A patent/JPH07500473A/ja active Pending
  • 1993-08-18 CN CN93116440.0A patent/CN1083643A/zh active Pending

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