JP2978243B2 - Synchronization method for mobile radio systems - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a method for synchronizing a mobile radio system without an overall time reference. That is, the system does not have a time base common to all mobile stations and base base stations therein. In particular, the invention is not only
A method for synchronizing a cryptographically superimposed random bit flow on a normal traffic flow during a paging or data transmission between a base station and a mobile station. What is needed is a method that can be simply applied to a so-called TDMA system. That is, it is a mobile radio system in which calls are transferred in claims and time slots in a time multiplexed device.

BACKGROUND OF THE INVENTION In mobile radio systems, especially TDMA systems, it is desirable to be able to maintain call security so as to prevent non-personnel from setting up the entire network and making calls. To meet this requirement, proposals have been made to encrypt calls, for example with reference to EP-A-27328.

The call between the base station and the mobile station has the function of cryptographically processing the method of voice messages between the communicating parties and converting the voice signal into a random sequence by means of a built-in electric telephone. For example, the audio signal can be overlaid with a relatively long (several minutes) random sequence of bits. In this case, the cryptocurrency is also present in the knowledge of all bit patterns of the sequence and the time when the sequence was started. An authorized user can plug into the circuit module of the device that stores this sequence and the starting point, so that the received call can be decrypted.

DISCLOSURE OF THE INVENTION Some TDMA mobile radio systems do not have an overall time base. That is, it is a device of mobile telephony that includes a clock that is common to all systems and that can create the same time reference for all base base stations and mobile stations in the system. When not synchronizing from a signal or data / voice signal for some reason, the purpose of such a common time reference is to allow the mobile and base stations to synchronize with each other in certain frames and time slots. When transferring a call from one radio channel to another (hand-off), the loss of synchronization between the mobile station and the base base station is caused by a short interruption during the actual transmission or switching of the call. This is because it occurs. If the call is also encrypted, another problem may occur, such as reduced synchronization of the actual cryptographic key involved, thereby making re-encryption impossible.

These problems also occur when a cryptographic call is set up, but the problems are most pronounced during "handoff".

The present invention is based on another frame time sharing of the traffic flow (TDMA principle), which combines or "hands off"
It is also based on the access of a given cryptographic sequence for a relatively long time (on the order of 3 minutes) with respect to the time during which the event occurs. The invention is also based on encryption, which superimposes a bit sequence on the normal traffic flow (data or voice and signal). Prior to handing off the call or during a given time interval of the handoff where the synchronization of the cipher sequence is stopped, the unencrypted signal is affected, and the traffic flow is then reduced to the frame time interval. Encrypted with equal time bit sequences. This enables the synchronization data to be transmitted from the base base station to the mobile station at the same time as the encrypted traffic flow, and appears when normal encryption is started.

That is, it is an object of the present invention to achieve synchronization of cryptographic sequences during setup or "hand-off" calls in mobile telephone systems that do not have a common time reference.

The present invention is characterized by the following claims.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with reference to the accompanying drawings.

FIG. 1 is a schematic diagram of two base base stations and a mobile unit, FIG. 2 is a time lapse diagram of transmission and reception based on the TDMA principle,
Time diagram of a cipher by Figure 3 is the manner desired, and Figure 4 shows a more detailed signal diagram of a time interval given by E ₁ of FIG. 3.

FIG. 1 shows schematically two base base stations BS ₁ and BS ₂ ,
And displaying a mobile base station MS is assumed to move from the base the base station BS ₁ to the base base station BS _2. Base The base station BS ₁ receives the traffic with a hexagon within area C _1, the base base station BS ₂ receives the traffic with a hexagon within zone C _2. Hex sections C ₁ and C ₂ have a common boundary G. Mobile base station MS
There voice quality for the supplied bound call by the base base station BS ₁ over the radio channel K ₁ given when the near Nuisance the boundary G is reduced. By measuring and calculating the electric field strength of the radio signal according to well-known principles, BS ₁ to MS
New radio channel K ₂ is switched to. The new channel K ₂ is supplied by BS _2. During the actual switching sequence with a duration of about 100 ms, the MS does not receive and the receiving circuit of the MS determines the traffic flow, i.e. the time position of the frame and the base station BS ₁
Out of synchronization of the time slot from the.

FIG. 2 shows the transmission and reception of frames (represented by RX and TX, respectively) of the mobile station MS.

Traffic flow before the "hand-off" is assumed to be encrypted by a constant electric Ken E _2. The electric train consists of a one-bit sequence or a longer, random sequence portion E (eg, about 3 minutes in length), which is superimposed on the traffic flow via the additional bits of Mogello 2 for the bits. As will be appreciated, the hand E is notified to the mobile station MS when it thinks it will send and receive calls, and the base station BS
₁ sends data about the starting time point, ie the position in sequence E where the bit flow starts. That E ₂ is informed to the mobile station MS. This encryption technique is known in the art.

FIG. 3 shows the time course of the display of the application method during "hand-off". Base The base station BS ₁ communicates with the mobile station MS, and the communication (voice) has, Ken encryption conductive until the time point t ₁
It is assumed to be encrypted by the E _2. Hand-off occurs at time t _1.

When the "hand-off" process in time t ₂ is completed, MS is synchronized with the new base base station BS _2. That is, a synchronization sequence indicating the time point of the frame and the assigned time slot for the paging communication continued between the BS ₂ and the MS is provided by the control provided by this base base station during the time t _{1 to} t _2. It is transmitted to the channel (SY in FIG. 2). This is done in a well-known manner by the MS correlation step. That is, at time t = t _2, there is a voice / data transmission frame synchronization between the BS ₂ and the MS, and not for encryption. Time t = t ₂
In the base the base station BS ₂ is conductive Ken encryption E ₂ transmits a signal unencrypted indicating the time to resume.
That is, BS ₂ informs time point t ₃ . Traffic flow (audio / data) is encrypted in the next frame by E ₁ electroscopic consisting periodic random bit sequence having a synchronizing equal to the frame interval. Until electrostatic Ken encryption E ₂ is initiated by the B _2, which causes the count of the frame interval to the mobile station MS (it was informed by a signal which is not encrypted).
Perhaps E ₁ Ken encryption collector seems to consist of only a plurality of zero. That (interval, t ₂ ~t ₃₎ The traffic flow in the next frame is not encrypted and transmitted. The presence of a frame period in the control channel SY from the time point t _2, even though the mobile station MS is not the presence of electrostatic tendon cycle bit sequence E ₁ can anyway counting the number of frame intervals.

Figure 4 is in more clearly displaying the sequence between the time interval t ₂ ~t _3.

According to Figure 3, the mobile base MS at time t ₂ is synchronized to the new base base station BS _2, if encryption is not used, the normal traffic flow (data, voice, synchronization) must be initiated . However, synchronization is lost for bit flows encryption conductive Ken E ₂ by time t _1. Therefore, sending to the electrostatic tendon encryption E ₂ is started, the signals S ₁ indicating whether more frames much based base station passes to the MS. This number of frames is assumed to be 13 in FIG. Commonly known FACCH formed by received time slots in a single frame, seen in FIG.
This message is expected to be transmitted in an unencrypted form (high speed control channel). That this time slot is located on the frame R _1. From frame R ₁
Until R _6, paging information that is not encrypted it is transmitted, encrypted by E ₁ electroscopic. As described above, this electric train is a time bit sequence that has an equal time during one frame and can be superimposed on the call information by the addition of Mogello 2. As a result, the mobile station MS
The time to start counting and the number of counted frame intervals are also foreseen. When the mobile station confirms this confirmation signal A ₁ is sent back to the base base station BS _2, it is received by the frame R _6. When the base base station BS ₂ receives this signal, the base BS to the frame R ₁₃ matching the number becomes equal to the time period of the frame, i.e. electrostatic tendon encrypted by E ₂ is started (t = t ₃₎ stand by.

That base base station BS ₂ waits confirmation signal A ₁ given time to receive the (time equal to 5 frame intervals in Figure 4). For some reason, in a given time, when this signal is not received by the base the base station BS _2, the signal S ₂ is transmitted to the frame R ₇ again, a new check signal A ₂ is awaited. For example, signals A ₁ for difficult ambient conditions for spacing fading or signal A ₁ is transmitted correctly is sometimes disappear. That is, the number of frames (here, R ₁₃ ) from the base base station BS ₂ must be large enough to enable the use of repetitive signals, as performed as described above.

The signal delay between the base base station and the mobile station is assumed in FIG. 4 to be about 2-3 frame intervals (about 15 ms). This delay also needs to be considered. That is, it is preferable that the encryption time point t ₃ is selected, so that t _{2 to} t ₃
It is assumed that the maximum number of times of propagation exceeds four. It is not difficult to calculate this because the mobile station has two hexagonal areas in FIG.
This is because it is located at the boundary between C ₁ and C ₂ , that is, at the maximum distance from the base base station.

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventors: Persson, Bengt, Ingbe S., Sweden-182 51 Dursholm, Box 42 (58) Fields investigated (Int. Cl. ⁶ , DB name) H04B 7/26 H04Q 7 / 00-7/38

Claims (4)

(57) [Claims] A data message (D) and a signaling message (S) between a first base station (BS1) and a mobile station (MS) include a bit flow selected at random, said message (D, S). ) Is transmitted in a frame having a time slot encrypted by being superimposed on the mobile station, and lacks a global time reference. Base station (B
When handing over the communication to S2), the time at which the message (D, S) is transmitted from the first base station to the second base station is counted, and the lack of the time reference causes the synchronization of the random bit flow to be lost. Any time period (t1 to t3)
In the method, the encryption (E2) is suspended in the synchronization method, and after the end of the handover of the message (D, S), the number of frame intervals (R2-R13) passed until the encryption is resumed. The unencrypted signal (S1) indicating the counted time (t3) is transmitted from the second base station (BS2) to the mobile station (MS).
A synchronization method characterized by being sent to 2. The message up to the time (t3)
2. The method according to claim 1, wherein the transmission is performed by means of an encryption sequence (E1) consisting of a periodic bit sequence whose period is equal to the frame interval. 3. The synchronization method according to claim 1, wherein the mobile station (MS) transmits a confirmation signal to the second base station (BS2) when receiving the unencrypted signal (S1). 4. If the second base station (BS2) does not receive the acknowledgment signal after an elapse of an arbitrary time, another unencrypted signal (S2) is the same as the unencrypted signal (S1). 4. The method according to claim 3, wherein the confirmation signal is sent to the second base station having a confirmation signal.