JP2003510862A - Link selection in communication systems - Google Patents

Abstract

(57) Summary At least one active link is selected for packet data communication in a wireless communication system. The reverse link is measured for a plurality of active base transmitting stations (102 to 104) operating on the mobile station (108). The subset of active links with the highest signal measurements is selected for forward transmission of at least one packet data communication.

Description

Detailed Description of the Invention

TECHNICAL FIELD OF THE INVENTION The present invention relates to forward channel control, and more particularly, to an apparatus for selecting a forward link with low overhead.

BACKGROUND OF THE INVENTION In code division multiple access (CDMA) systems, communication occurs on the forward link over multiple channels from different radio base station devices (Bse Transceiver Stations (BTS)). The forward link is a link for communication from the BTS to the mobile station (MS). Reverse link from MS to BTS
Is a link for communication to. The channel in which communication occurs in the forward direction (forward direction) is generally called the "active set", and the channel of the active set is the channel that the mobile station receiver is modulating. So-called "adjacent set"
Channels are also unmodulated but are monitored for soft handoff.

As the number of channels through which signals are communicated to mobile stations increases, diversity performance (
The diversity performance is better. However, this improvement in performance is achieved at the expense of overall system capacity as the number of channels available to other mobile stations decreases, and at some loading point, the diversity gain is at the expense of all soft handoff forward links. It will be below the extra power transmitted above. Therefore, CDMA
In a system, performance and capacity are in conflict.

For packet data, the bit-leveler rate (BER) is an automatic repeat request (BER).
ARQ). The target forward error rate (FER) is expected to be in the range of 10-15% for packet data. When targeting this error rate, which is high compared to the target error rate of 1% in voice transmission and the error rate of 0.1% in circuit data transmission, the multipath diversity benefits due to soft handoff are significantly reduced. Therefore, there is a need for improved forward channel selection for packet data communication in CDMA systems. (Detailed description of the drawings)

At least one active link has been selected for packet data communication in a wireless communication system. The reverse link is measured for multiple active base transmitter stations (102-104) serving a mobile station (108). The subset of active links with the highest signal measurements is selected for forward transmission of at least one packet data communication.

Forward transmission schemes have been proposed for transmitting data on the best forward link or a subset of the best forward transmission links. Link performance results for static and highly Ricean channels, such as those experienced by fixed wireless terminals, allow data to be communicated on the best forward link of all active wireless base station equipment. It shows that it is more preferable.
By transmitting on the upper one or two forward links instead of all the forward links, between the wireless base station device and a basic facility (network) that controls, integrates, and activates the wireless base station device. The communication bandwidth (return bandwidth) required in (1) is reduced. Said infrastructure is commonly known as Cell Base Station Controller (CBSO), or Radio Network Controller (RNC) or Selection / Distribution Unit (SDU), the desired FER for a given user. N + 1 (eg, n associated with soft or softer handoff to achieve
+ 1 = 3) When the total output from the forward links exceeds the output required when n or less forward links are used, the transmission on the upper two forward links can improve the system capacity. is there.

As used herein, a link is a collection of channels used to communicate between a mobile station and a base station. Channels include dedicated control channels, pilot channels, supplemental channels, paging channels, and the like.

A cellular system 100 is shown in FIG. The illustrated cellular system 100 is a code division multiple access system including a plurality of wireless base station devices (BTS) 102 to 104 that are in communication with mobile stations MS 108 that communicate on their respective wireless channels. Those skilled in the art will appreciate that there will generally be more than two base transceivers and more than one mobile station in a system. Base station (B
The access transmission stations 102 and 103 are connected to the mobile switching system network 110. CDMA cellular systems of this kind are known.

In the CDMA system 100, the voice target frame error rate (FER) is 1
%. The circuit target FER is 0.1%. For these target FERs, soft handoff provides diversity gain. Therefore, it is desirable to use all available soft handoff links. However, for third generation (3G) packet data applications, the target FER is expected to be in the range of 10% to 15%, so that the desired bit level rate (BER) is dependent on automatic repeat request (ARQ). To be achieved. The multipath diversity benefit from soft handoff is much smaller when targeting these very high FERs as compared to targeting 1% in voice or 0.1% in circuit data.

Each communication path between the base terminal stations 102 to 104 and the mobile station 108 has a forward link and a reverse link. The network 110 is supposed to select at least one or more forward links with the least transmission loss. If the mobile station measures the forward transmission link from the base stations 102-104, then the measurements generated by the mobile (eg IS95 standard and I
The SNR (Ec / lo) measurements sent using the pilot strength measurement message (PSMM) as in the S2000 standard must be returned to the radio base station equipment and then the network 110. This requires message overhead and is inappropriate. To detect and determine the best subset of active channels, the overhead can be largely eliminated by using reverse channel signal measurements. A subset of the active channels is to be used for forward channel packet data communication.

For example, each of the base station transceivers 102-104 derives a reverse link signal / noise ratio (SNR) from the reverse link signal received from the mobile station 108.
And the measured overall interference plus noise power (RSSI) makes it possible to determine the forward channel packet data channel. The advantage of using the reverse link signal is that the mobile does not have to use communication to transmit the forward link signal / interference ratio (SIR) to the base station transceivers 102-104. The reverse link channel SIR is a symbol energy (win) according to a reverse channel pilot (IS2000 standard) or Walsh.
Ning Walsh symbol energy) (IS9SA, B standard)
Can be estimated from Also, the reverse link channel SIR is Ew /
Proportional to Nt or pilot Ec / Nt. The resulting measurement (SNR) is the signal / (thermal) noise + interference ratio calculated from the reverse link SIR and RSSI.

Each active radio base station device (BTS) 102-104 is typically resident in the radio network controller (RNC) or central base site controller (CBSC) on a frame-by-frame basis. The reverse signal / noise ratio (SNR) is transmitted to the network selection and distribution unit (SDU) 110 that operates. If one of the currently active BTSs (ie, one of the BTSs in the mobile station's active set) involves more than one sector in the call (this is typically a softer handoff). Called, more than one station is in communication with the mobile), the best signal / noise ratio for the soft handoff sector is selected as the signal / noise ratio of the active base transmitting station. The network (SDU) 110 selects either the best one forward link or a subset of the best active forward links for packet data transmission. Thresholds driven by current service options and / or target FER may be used for best channel selection. Depending on the threshold, the best forward link or the best forward link channel subset is selected. The SDU synchronizes both BTSs and MSs to send and receive forward data.

FIG. 2 is a functional flowchart showing the operation of the network 110. The network 110 is, for example, a mobile switching center or an operating wireless base station device (BTS2 103).
Shown in FIG. The radio base station device 103, at step 216, as is known in the art, lock filtered rake fingers (lock f).
iltered lake finger) information is obtained. BTS Step 2
For each of the 14 locked and filtered Rake finger information signals, the signal / interference ratio is calculated at step 214. This SIR information is provided to the signal / noise ratio estimation 212. The sum of the signal plus noise output is also estimated at the base station transceiver (RSSI). Also, if each quantity is decibel, the interference increase (RISE) 108 above the receiver thermal noise floor is RISE = RSSI-RSSIn.
Calculated as load. The resulting RIS, as shown in step 220.
E is also input to the signal / noise ratio estimate 212. At step 218, a sliding filter known in the art filters the baseband input. The resulting filtered signal is also used for SNR estimation as shown in step 212. The SNR is communicated to the network 110 along with other signal measurements from the other active or active BTSs 102, 104.

The network 110 is responsible for setting up a threshold for the desired FER (indicated by step 204) at the network server in step 206. In the preferred embodiment, the threshold indicates in dB how close the weaker link should be to the strongest link. If the threshold is 5 dB, then S within 5 dB for the strongest transceiver
The base station transceiver with NR or signal strength (S) will be part of the reduced active set and will be assigned to the forward link on the next transmission. The higher the FER goal, the lower the threshold (eg, for a high goal, the threshold may be 3 dB). At step 208, the best forward link selection is made. This is the step in which a network controller, which may be a computer or microcontroller, or other suitable system, selects a subset of active or active BTSs for data packet transmission. Once selected, the packet of data is the selected active BTS
Be communicated by. A new BTS may be selected for each packet communication, or a BTS operating at a predetermined interval may be selected.

One method of calculating the SNR is the signal / interference ratio (SIR) and noise floor (RIS).
E) above the reverse link interference increase. The SNR can be calculated as follows.

SNR (i) = SIR (i) + RISE (i), in dB, i = 1, ...
N (1) In the above formula, i represents the ith operating wireless base station device (BTS), and N is N
Represents a soft handoff leg. The SIR can be calculated by accumulating the filtered Rake finger energy values. SIR energy is
Reverse link pilot or control channel or data channel (eg,
In IS95 and IS2000, the channel is the fundamental channel (FC
H), dedicated control channel (DCCH) or supplemental control channel (SC
H)) can be based on the modulated symbol energy of the reverse link signal received by the BTS, resulting in:

[0017]

[Equation 1] E (j) represents the jth filtered finger energy value and M represents the M finger. The Reverse Link Interference Increase (RISE) for the noise floor is calculated as follows:

RISE (i) = (RSSI (i) −RSSInload (i)) (3) In the above formula, RSSI is the radio base station apparatus (BTS) received signal strength, which is known in the art. Is updated every frame as follows. RSS Inolo
ad (i) is the BTS received signal strength when the BTS is not loaded with any traffic. RSSInload (i) can be determined by site calibration, or calculated based on the expected nominal noise figure for the BTS, as is known in the art. Over a period of time (
It is possible to obtain the RSSI by low pass or ranking or by means of the middle term filtering the baseband front end signal samples (eg 2 seconds). Note that it is possible to calculate the signal energy (S) and use it in equation 4 below instead of SNR. More specifically, S (i) = SIR (i) ^* RSS
Compute S using the RSSI for I (i). For those skilled in the art, in dB,
It will be appreciated that S (i) = SIR (i) + RSSI (i). S
The IR can also be estimated from the decoder metric, ie the decoder metric, such as the (data) symbol energy according to Walsh generated in the incoherent receiver of IS95A and IS95B compliant communication devices.

The SDU selection function selects the best forward link Flink (k) or a subset of the best forward links based on a threshold as given by

FIink (k) = Best (SNR (1), SNR (2), ... SNR (
N)) (4) where k = 1, 2 ..., K is the total number of selected forward links that exceed the threshold. The Best () function selects the best link, or subset of links, for the soft handoff leg from the available SNR measurements. Alternatively, in another preferred embodiment, the Besto () function is based on the signal power measurement S (i) as noted above.

It is possible that updates to the best forward link will be generated frequently. Frequent updates result in smaller delays and more accurate selection of the best forward link for the next scheduled packet transmission. The more link selections there are, the more likely bursts will be received at the lowest power possible without error. As a result, this results in higher system capacity.

One best forward link selection scheme is a mobile-measured forward link measurement Ec / lo (eg PS, as is known in voice transmission).
It is proposed to be independent of the pilot Ec / lo measurements sent by the MM) and only the reverse link signal measurements such as RSSI or SNR measurements at the BTS. Each active radio base station equipment (BTS) supplies its reverse link SNR to the network SDU. The SDU selects at least one forward link whose reverse link SNR exceeds a predetermined threshold and has the best signal level. Then the SDU sends the data burst B
Synchronize the TS and the mobile station (MS) that receives the data burst. The scheme provides improved performance for packet data, and by choosing the best subset for transmission, in keeping with soft handoff diversity benefits, maintains flexibility for circuit data or voice.

[Brief description of drawings]

FIG. 1 is a block diagram showing a cellular communication system.

FIG. 2 is a functional block diagram showing the operation of the network.

─────────────────────────────────────────────────── ─── Continued front page    (81) Designated countries EP (AT, BE, CH, CY, DE, DK, ES, FI, FR, GB, GR, IE, I T, LU, MC, NL, PT, SE), OA (BF, BJ , CF, CG, CI, CM, GA, GN, GW, ML, MR, NE, SN, TD, TG), AP (GH, GM, K E, LS, MW, MZ, SD, SL, SZ, TZ, UG , ZW), EA (AM, AZ, BY, KG, KZ, MD, RU, TJ, TM), AE, AL, AM, AT, AU, AZ, BA, BB, BG, BR, BY, CA, CH, C N, CU, CZ, DE, DK, EE, ES, FI, GB , GD, GE, GH, GM, HR, HU, ID, IL, IN, IS, JP, KE, KG, KR, KZ, LC, L K, LR, LS, LT, LU, LV, MD, MG, MK , MN, MW, MX, NO, NZ, PL, PT, RO, RU, SD, SE, SG, SI, SK, SL, TJ, T M, TR, TT, UA, UG, UZ, VN, YU, ZA , ZW (72) Inventor Chen, Shan Yang             United States 60047 Re, Illinois             Iku zurich fox moor             Lane 833 F term (reference) 5K067 BB04 BB21 CC08 DD42 DD44                       DD45 EE02 EE10 EE24 JJ11                       JJ31

Claims (12)

[Claims] 1. A method for selecting at least one active link for packet data communication in a wireless communication system, the method comprising: measuring reverse links at a plurality of active base transmitting stations; Selecting the subset of active links with the highest signal measurements for forward transmission. 2. The method of claim 1, wherein the subset comprises a single channel. 3. The method of claim 1, wherein the measurement is a function of reverse link RSSI. 4. The method of claim 3, wherein the measurement is a function of the reverse link signal / noise ratio. 5. The method of claim 1, wherein the measured value is a function of the reverse link signal / noise ratio. 6. The method of claim 1, wherein the measurement is a function of RSSI and SIR. 7. The method of claim 1, wherein the measured value is decibel (dB) and RSSI + SIR. 8. The method of claim 1, wherein measurements are generated and the measurements are returned to a network device to determine the best forward link for all frame intervals. 9. The method of claim 1, wherein measurements are returned from all active base station transceivers to the network device every frame interval. 10. The method of claim 1, further comprising determining the best forward link using measurements from all serving BTSs for the mobile station. 11. The measured value is a decoder metric.
The method of claim 1, which is a function of 12. The method of claim 1, wherein the subset of active links used for packet communication is less than the total set of active links.