In order to allow users to access various networks and services ubiquitously, an increasing number of UEs are equipped with multiple radio transceivers. For example, a UE may be equipped with LTE, WiFi, and Bluetooth transceivers, and GNSS receivers. One resulting challenge lies in trying to avoid coexistence interference between those collocated radio transceivers. Figure 4-1 below shows an example of coexistence interference.
3GPP initiated a Study Item (SI) in Release-10 timeframe to investigate the effects of the interference due to multiple radios and signalling. This study is detailed in 3GPP TR 36.816 (see link at the end).
Due to extreme proximity of multiple radio transceivers within the same UE, the transmit power of one transmitter may be much higher than the received power level of another receiver. By means of filter technologies and sufficient frequency separation, the transmit signal may not result in significant interference. But for some coexistence scenarios, e.g. different radio technologies within the same UE operating on adjacent frequencies, current state-of-the-art filter technology might not provide sufficient rejection. Therefore, solving the interference problem by single generic RF design may not always be possible and alternative methods needs to be considered. An illustration of such kind of problem is shown in Figure 4-2 above.
The following scenarios were studied:
- LTE coexisting with WiFi
- LTE coexisting with Bluetooth
- LTE Coexisting with GNSS
Based on the analysis in SI, some examples of the problematic coexistence scenarios that need to be further studied are as follows:
- Case 1: LTE Band 40 radio Tx causing interference to ISM radio Rx;
- Case 2: ISM radio Tx causing interference to LTE Band 40 radio Rx;
- Case 3: LTE Band 7 radio Tx causing interference to ISM radio Rx;
- Case 4: LTE Band 7/13/14 radio Tx causing interference to GNSS radio Rx.
In order to facilitate the study, it is also important to identify the usage scenarios that need to be considered. This is because different usage scenarios will lead to different assumption on behaviours of LTE and other technologies radio, which in turn impact on the potential solutions. The following scenarios will be considered:
1a) LTE + BT earphone (VoIP service)
1b) LTE + BT earphone (Multimedia service)
2) LTE + WiFi portable router
3) LTE + WiFi offload
4) LTE + GNSS Receiver
The SI also proposes some ways of reducing the interference and is work in progress at the moment.
Reference:
3GPP TR 36.816 : Study on signalling and procedure for interference avoidance for in-device coexistence; (Release 10).
Some of you may have noticed that the new and revamped 3GPP website have recently started offering 3GPP specs and features tutorials via The SpecTools. There is quite a lot of useful information and most of it is premium but a lot is free as well. 
The above figure from R2-106188 shows that an extended wait time could be added in the RRC Connection Reject/Release message in case if the eNodeB is overloaded. The device can reattempt the connection once the wait time has expired.
In R2-110462, another approach is shown where Core Network (CN) is overloaded. Here a NAS Request message is sent with delay tolerant indicator a.k.a. low priority indicator. If the CN is overloaded then it can reject the request with a backoff timer. Another approach would be to send this info to the eNodeB that can do a RRC Connection Reject when new connection request is received. 
CES2011: NEC dual-screen Android Cloud Communicator LT-W hands-on
Source: Dilbert
Given the many possible combinations of layers and carrier aggregation, many configurations could be used to meet the data rates in Table 4. Tables 5 and 6 define the most probable cases for which performance requirements will be developed.
From a presentation by Huawei at the New Zealand Future Wireless Technologies Seminar. The presentation is available here.
