Abstract:
A wireless communication system operating in the presence of the periodic noise signals such as from a microwave oven, the communication system, including at least two wireless communication stations with each station including a transceiver, each such transceiver. Each transceiver includes a detector for detecting periodic noise signals and producing a first signal indicating the presence of noise signal&#39;s quiescent period and second signals indicating the end of quiescent periods of such periodic noise signal. A controller responsive to the first and second noise signals controls the transceiver to provide effective communication with an other transceiver which minimizes the noise effect of the periodic noise signal. The transceiver transmits information concerning the detected quiescent period for use by the other transceiver to determine when to transmit during such quiescent period.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     Reference is made to commonly-assigned U.S. Provisional Patent Application Ser. No. 60/118,798 filed Feb. 5, 1999, by Carlson et al. entitled “Communicating in the Presence of Periodic Microwave Noise.” 
    
    
     FIELD OF THE INVENTION 
     This invention relates to a digital wireless wideband RF communication system operating in periodic noise environments. Such a system is useful, for example, for communicating digital data at high data rates; e.g. rates greater than 1 Mega bits per second (Mbps). 
     BACKGROUND OF THE INVENTION 
     With the advent of digital photography, the wireless transmission of digital images, for example between a portable transmitting device like a digital camera and a receiving device such as a personal computer or other image appliance such as a printer, has become a desirable feature. High data rate transmissions are desirable because digital images represent a large amount of data and short transmission times are needed. Short transmission times result in shorter wait times while an image is being transferred from a camera to a receiver and in reduced battery power consumption. 
     Although there are several useful communication bands available for such a digital communication system, the 2.4 to 2.5 GHz ISM Band is particularly attractive because the band is unlicensed and available internationally. However, a major problem exists with the use of this band for wireless communication. The band is allocated for microwave ovens and other devices, which as described below, generate a great deal of periodic noise in the band. Other communication bands like the 5.75 GHz band can also have periodic noise generators present. For the purpose of describing the present invention, references will only be made to periodic microwave noise as is present in the 2.4 to 2.5 GHz ISM band. It will be understood that the same principles can be used in the presence of any other kind of periodic noise in any communication band. 
     Radio frequency (RF) transmissions in the 2.4 to 2.5 GHz ISM Band have historically had to deal with the presence of man-made noise from microwave ovens that predominately operate in the center of this band at 2.45 GHz. The noise emanates from the oven by leakage through the enclosure of the oven. The leakage noise is periodic and has a radiated output power approximately 20 dB greater in strength than that allowed by the FCC for operation of Part 15 non spread spectrum radios. With over 200 million microwave ovens in use throughout the world, they are by far the greatest and most significant source of noise in this band. In addition microwave lighting and illumination systems are soon to be in use in the same band creating additional noise interference. Some examples of locations where it would be desirable to transmit images in the presence of periodic microwave noise are in the home (particularly in the kitchen), or in a supermarket or department store where a photo kiosk may be located near a microwave oven or lighting system. 
     One possible way to communicate in the presence of microwave noise is to use a spread spectrum communication technique. One type of spread spectrum technique spreads the signal over a band which is much larger than the bandwidth of the signal so that the narrow band noise from the noise source has a reduced effect on the demodulated signal to noise ratio. This technique however is relatively expensive to implement, significantly limits the data throughput (e.g. by a factor of 8 or more) and does not work well if the receiver is located very close to the noise source. Another way to communicate in the presence in the presence of microwave noise is described in U.S. Pat. No. 5,574,979, issued Nov. 12, 1996 to West, entitled “Periodic Interference Avoidance in a Wireless Radio Frequency Communication System.” This patent demonstrates a potential solution by avoiding microwave oven periodic noise by sensing the periodicity of the AC power line main in which the oven is connected to. Unfortunately this technique does not work for periodic noise sources other than microwave ovens or in cases where multiple microwave noise sources on different phases exist. This technique also does not work in cases where the RF communication equipment is battery powered and no connection to an AC power main can be made, nor can the AC main E field radiation be received by the RF communication equipment. Furthermore this approach does not address the problem where one of the wireless communication stations can sense the noise, but the other wireless communication station cannot; when both stations are subjected to noise having different characteristics; or when three or more stations are trying to communicate and one or more are in a noise environment. 
     There is a need therefore for an improved means of digital communication in environments with periodic noise. 
     SUMMARY OF THE INVENTION 
     This need is met by a wireless communication system operating in the presence of periodic noise signals such as from a microwave oven, that includes at least two wireless communication stations with each station including a transceiver, each such transceiver. Each transceiver includes a detector for detecting periodic noise signals and producing a first signal indicating the presence of noise signal&#39;s quiescent period and second signals indicating the end of quiescent periods of such periodic noise signal. A controller responsive to the first and second noise signals controls the transceiver to provide effective communication with an other transceiver which minimizes the noise effect of the periodic noise signal. The transceiver transmits information concerning the detected quiescent period for use by the other transceiver to determine when to transmit during such quiescent period. 
     Advantages of the present invention include: 
     1. When each station can tell the other station(s) when periodic microwave signals will prevent reception, the transmitting stations can wait to transmit during the proper time. While waiting, systems may be powered down to reduce energy consumption, reduce interference with other devices and more efficiently control data flow to and from the host CPU; and 
     2. If two stations have interference between them, either partially or completely overlapping in time, the stations can look for other available stations with which to communicate in a more efficient manner, or wait until the first station is more available. 
     This invention is less expensive than one that uses a master clock to assign a global time reference to all stations and their quiescent periods. Such a system requires expensive accurate internal time bases or access to a Global Positioning System time base such as used by Code Division Multiple Access cellular systems. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a plot of a typical RF waveform produced by a microwave oven; 
     FIG. 2 is a block diagram of a transceiver according to the present invention; 
     FIG. 3 is a block diagram of a microwave oven detection circuit; 
     FIG. 4 is a plot of the sync clock signal generated by the microwave oven noise detection circuit of FIG. 3; 
     FIG. 5 is a schematic diagram depicting the situation wherein both stations are receive interference from the same noise source; 
     FIG. 6 is schematic diagram depicting the situation in which only one of two stations is receiving interference; 
     FIG. 7 is a schematic diagram depicting the situation in which both stations are being receiving interference from different noise sources; 
     FIG. 8 is a schematic diagram depicting multiple stations with one noise source; 
     FIG. 9 shows an example packet format that can be used to communicate quiescent period, duration, signal strength and type of service data to other stations; and 
     FIG. 10 is a timing diagram based on FIG. 4 showing when the “start of quiescent period” and “end of quiescent period” packets would be transmitted. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     In addressing the above problem, it is understood that the energy emitted by a microwave oven is periodic at a frequency based on the AC power line voltage frequency. Referring to FIG. 1, a typical noise energy waveform  10  produced by a microwave oven is shown. The source of the RF noise energy is the magnetron within the microwave oven, which is driven by the AC power line. The output noise spectrum is pulsed at approximately a 50% duty cycle synchronized to the AC line voltage. The frequency of the periodic microwave signal us usually 50 or 60 Hertz or 100 or 120 Hz for bridge rectified systems. According to the present invention, this pulsed noise is detected and communication is conducted during the quiescent periods, that is during the periods 11 (between times T 1  and T 2  and times T 3  and T 4 ) when the microwave oven is off. 
     Referring to FIG. 2, a system for communicating digital data according to the present invention includes a transceiver  12  for communicating in the presence of microwave oven. The term “transceiver” means a transmitter-receiver combination. The transceiver includes a transmitter  14 , a receiver  16 , and a transmit/receive switch  18  that selectively connects an antenna  20  to the transmitter or the receiver. The transmitter  14  is a standard design 2.4 to 2.5 GHz transmitter employing any known modulation scheme such as frequency shift keying FSK or quadrature phase shift keying QPSK. The receiver  16  is a standard design 2.4 to 2.5 GHz receiver with the capability of demodulating a 20 Mbps FSK or a 40 Mbps QPSK signal. The FSK demodulator in the receiver  16  is for example a Motorola MC13155 integrated circuit. The transceiver  12  also includes a microwave noise detect circuit  22  connected to the RSSI  17  (Receive Signal Strength Indicator) of the receiver  16 . 
     The transceiver  12  is controlled by a microprocessor  24 . The microprocessor  24  may for example be a microprocessor that is also used to control an image appliance  26  (i.e. camera, printer, kiosk, or personal computer), or may be a microprocessor that is specifically supplied with the communication system. The microprocessor  24  controls the transmit/receive switch  18 , prepares the data from the image appliance  26  to be transmitted by transmitter  14 , and receives the data from the receiver  16  to supply received data to the image appliance  26 . 
     Referring to FIG. 3, microwave noise detect circuit  22  uses the RSSI signal  17  from the receiver  16  to generate a sync clock  30  and a Lock detect  28  signal as described below, which are supplied to the microprocessor  24  for controlling the communication of data during quiescent periods in the microwave oven noise  10 . The main function of this circuitry  22  is to lock on to the envelope of the microwave oven noise  10  using the AM detector in the RSSI circuitry (not shown) to generate a Lock detect signal  28  and a synchronization (Sync) clock  30  for the microprocessor. 
     The Lock detect signal  28  informs the microprocessor  24  that an AC line frequency periodic microwave energy signature is present. To generate the Lock detect signal  28 , the RSSI  17  input signal coming from the receiver is first buffered  46  and provided both to a phase locked loop circuit  56  and sync clock generator circuitry  32 . The phase locked loop circuit  56  includes a Voltage Controlled Oscillator (VCO)  52 , a Phase Comparator  48  that produces a phase error output signal  54  and a Low Pass loop Filter (LPF)  50 . The circuit is designed to provide a Lock detect signal  28  if it is supplied with a 50 to 120 Hertz RSSI signal  17 . The circuit is commercially available in integrated circuit form from manufacturers such as Motorola. A commonly used part number is CD4046. 
     FIG. 4 shows the Sync clock signal  30  referenced to the microwave oven noise energy in FIG.  1 . Sync clock signal  30  is generated separately from Lock detect signal  28  using sync clock generator circuitry  32 . Sync clock signal  30  is identical to the RSSI  17  signal in its pulse width, frequency and duty cycle. It is used to predict when the microwave oven will be in the quiescent state. This detect and latch process is necessary since the RSSI  17  signal will not be able to separate the microwave oven noise from the transceiver activity, once data communications commences. Binary counters  34 ,  36  sample the RSSI  17  high and low periods and load the result into pre-setable counters  38 ,  40 . Once the data is loaded, the Sync clock  30  is generated by monostable multivibrator  42  without the microwave signature provided by the RSSI signal  17 . The Sync clock  30  is provided to the microprocessor  24  and is used to enable the transmitting of the image data only during the predicted quiescent or “off” periods 11 in the microwave oven&#39;s noise signature. The Sync clock  30  continues to run until the microprocessor determines it is no longer needed, or that the quiescent period has shifted in phase. The microprocessor then resets the microwave noise detect circuitry  22  to obtain a new Sync clock signal  30 . 
     Phase shifting can be caused by noise from multiple microwave ovens on different power phases (i.e. the duty cycle of the quiescent time available for communication is reduced). If three ovens are on simultaneously using three different AC phases, the RSSI signal will be high the entire AC cycle and there will be no Lock detect signal  28 . The microprocessor  24  will cause the transceiver to search for a quiet channel. Once a lock is established however, the microprocessor  24  knows when to stop using the Sync clock either when the receiver at the far end signals the transmitter that the microwave oven noise has stopped and it has verified the noise has stopped by listening, or its Lock detect  28  goes high again synchronous with the Sync clock signal  30 , indicating that the oven noise is gone, and the transmitter is causing its own lock detect signal. 
     This approach works for different AC line frequencies, and works even if there are multiple ovens, or ovens on at least two phases of an AC distribution system, and other periodic microwave energy sources. 
     The above described system works most simply when the receiving and transmitting stations  62 ,  64  are both in the same range of the microwave oven noise source  58  as in FIG. 5, and both stations can determine the quiescent period for themselves. This range  60  is defined by the locus of points where the transmitter signal to oven noise ratio is greater than for example about 12 dB, corresponding to a good signal reception condition. 
     In FIG. 6, the transceiver station “A&#39;s”  62  ability to receive is affected by the noise from the oven  58  but station “B” is not. Note that even if station A&#39;s ability to transmit is not affected by the oven if we assume that station B can receive station A under normal conditions. It this arrangement, station B needs to be told when station A can receive it&#39;s signals. 
     In FIG. 7, Both stations A and B are in the presence of oven noise. In this scenario, both stations have to inform the other of their quiescent periods. If the ovens are on the same AC power phase, this case reverts to FIG.  5 . If the ovens are on different phases, and start at different times for different duration, the quiescent data must be transmitted to each station, and may occur at any point in the received packet sequence. The host or Media Access Controller must keep track of the status and phase of each station. 
     FIG. 8 shows the case where only one of three stations is affected by oven noise. In this case, stations B,  64  and C,  66  may decide to communicate and wait until A,  64  is no longer in a noisy environment, or until stations B and C have completed their communications. 
     To communicate information during quiescent periods, the data is communicated in a series of packets that are shorter than the quiescent period. The first packet of the series is called a start packet and it includes information about the presence and frequency of any detected noise and the identity of the station sending the packet. 
     Since the quiescent period is much larger than any one packet, one approach is to have short packets dedicated to representing the start and stop of the quiescent period for any station to broadcast. Another approach is to have the start packet contain the duration of the quiescent period whereby the stop packet is not needed. FIG. 9 shows a packet structure for accomplishing this function. FIG. 9 demonstrates “management” type packets, and Beacon “subtypes”  70  as defined by section 7.1.3 of the IEEE 802.11 wireless Ethernet. Packets subtypes can include: SOQP (Start of Quiescent Period) 68, EOQP (End of Quiescent Period) 72, and OS (Oven Stop). 
     FIG. 10 shows how the use of start and stop packets that would be transmitted with respect to the oven sync clock signal defined in FIG.  5 . If the transmitted start packet contains the duration of the quiescent period than a timer in the receiver would be used to keep tract of EOQP and a stop packet would not be sent. Once communicated the status of the receivers and transmitters are known. Decisions can be made when to communicate with each station based on it&#39;s availability. If the SOQP packets also contain the RSSI signal strength of the interfering periodic energy, additional decisions can be made based on the degree of interference. 
     In addition, since stations can transmit through interfering periodic microwave signals to receivers not affected by interfering periodic microwave signals, stations transmitting isochronous data or video streams such as USB devices or video devices can indicate the type of data (asynchronous or isochronous) in the SOQP or beacon packet and cause the receiver to enter a special mode. In this mode, the transmitter can continue to transmit and the receiver can receive without bidirectional flow control or packet control such as packet acknowledgment. 
     Furthermore, any system or subsystem of the communication or host device, not able to be used can be shut down or reduced in power when ever this quiescent period data indicates it&#39;s function will be unnecessary for a determined amount of time. This reduces power consumption and improves battery life for portable devices. 
     The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the spirit and scope of the invention. 
     Parts List 
       10  microwave oven noise energy wave form 
       11  quiescent (off) period 
       12  transceiver 
       14  transmitter 
       16  receiver 
       17  Receive Signal Strength Indicator (RSSI) 
       18  transmit/receive switch 
       20  antenna 
       22  microwave noise detect circuit 
       24  microprocessor 
       26  imaging appliance 
       28  Lock detect signal 
       30  Sync clock signal 
       32  Sync clock circuitry 
       34  binary counter 
       36  binary counter 
       38  pre-setable counter 
       40  pre-setable counter 
       42  monostable multivibrator 
       44  Sync Stop signal 
       46  buffer 
       48  phase comparator 
       50  low pass loop filter 
       52  Voltage Controlled Oscillator 
       54  phase error signal 
       56  phase locked loop 
       58  Microwave Oven 
       60  Range of oven noise 
       62  Transceiver station A 
       64  Transceiver station B 
       66  Transceiver station C 
       68  “Start of quiescent period” packet 
       70  Regular packet period 
       72  “End of quiescent period” packet