Abstract:
A network distributed seismic data acquisition system comprises seismic receivers connected to remote acquisition modules, receiver lines, line tap units, base lines, a central recording system and a seismic source event generation unit synchronized to a master clock. One or more high precision clocks is added to the network to correct for timing uncertainty associated with propagation of commands through the network. Seismic receivers and seismic sources are thereby synchronized with greater accuracy than otherwise possible. Timing errors that interfere with the processing of the seismic recordings are greatly reduced, thus enabling an improvement in subsurface geologic imaging.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS  
       [0001]     This application is a Division of pending application Ser. No.  10 / 653 , 645  filed Sept. 1, 2003. Said application Ser. No. 10/653,645 claims the benefit of U.S. Provisional Application No. 60/416,070 filed Oct. 4, 2002.  
       STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT  
       [0002]     Not applicable 
     
    
     FIELD OF THE INVENTION  
       [0003]     The present invention relates to seismic survey equipment. In particular, the invention relates to equipment assembly combinations and the synchronization of a widely distributed network of seismic receivers and seismic sources using both a wired and a wireless medium.  
       BACKGROUND OF THE INVENTION  
       [0004]     In principle, a seismic survey represents an analysis of the earth&#39;s geologic structure as indicated by seismic reflections from impedance discontinuities at lithologic interfaces. The analysis is influenced by seismic wave propagation velocities respective to the successively deeper geologic formations. A precisely-timed seismic source event, such as the ignition of buried explosives in a shallow borehole or a controlled mechanically-induced continuous vibration is launched at a precisely known location and time. The seismic source unit together with its controller, the seismic event generator, are designated collectively as the seismic source.  
         [0005]     Seismic wave reflections from this man-made seismic event are detected by a multiplicity of geophone or hydrophone sensor arrays located in a more-or-less orderly grid over the area of interest. A series of such seismic source events is initiated at varying positions over the area of interest. The positions of the seismic sensor arrays may be shifted to better receive the seismic reflections of interest prior to each successive seismic source event. The location of each seismic sensor array and each source event is precisely mapped.  
         [0006]     As a seismic wave from the timed event travels out from the source, reflections from that original seismic wave return to the surface where they are detected by the seismic sensor arrays. The sensor arrays respond to the receipt of a wave with a corresponding analog electrical signal. These analog signals are received by data acquisition modules that digitize and record the analog signal stream for retransmission to a central recording unit. Together, the seismic sensor array and the data acquisition module to which it connects may be termed the seismic receiver. Among the significant data digitized by data acquisition modules is the amplitude or the strength of the reflected wave. The time lapse between the moment the event occurred and the moment the amplitude of the wave is received is determined by the data acquisition system and is recorded either in explicit or implicit form. For each seismic source event and each array, amplitudes are sampled over a time range typically from zero to five seconds, for an impulsive source such as the buried explosive; or zero to twenty seconds for the continuous vibratory source, for example. Samples are typically repeated every 2 milliseconds, thus generating from two to ten thousand samples per seismic source event per source array in representative cases for impulsive and vibratory sources.  
         [0007]     In a single survey, there may be thousands of seismic source events each with thousands of seismic sensor arrays. Consequently, the data flow must be orderly and organized. For example, the data acquisition modules transmit digital sensor signal values in digital data packages containing a predetermined number of digital data bits. Each of these data packages may carry the identity of the specific seismic sensor array from which the data originates and the time it was received by the array in addition to the seismic signal amplitude value. The acquisition modules are programmed to transmit data packets respective to each seismic sensor channel at a predetermined frequency. The variable data in a data packet represents an instantaneous snapshot of the analog signal flow from the array channel. There may be numerous individual seismic sensor arrays transmitting respective analog signals to the data acquisition module on the same communication channel.  
         [0008]     Managing an orderly flow of this massive quantity of data to a central recording unit requires a plurality of geographically-distributed digital signal processing devices. The data acquisition modules convert the array analog data to digital data and transmit the digital data packets along receiver line cables (wired) or radio transmission (wireless) channels. Cables may be of various designs including both electrical conductor and fiber optic. Wireless channels are typically conventional radio but could also include light wave transmission.  
         [0009]     There may be numerous data acquisition modules transmitting data packets along a single receiver line or channel. Typically, two or more receiver lines connect with line tap units that further coordinate the data packet flow of numerous additional line tap units along a base transmission line for receipt by a central recording unit. The base line may have a higher speed transmission capability than the receiver line to facilitate the flow requirement.  
         [0010]     One of the key difficulties of a widely distributed seismic data acquisition system is that the transducers which measure the seismic vibrations of the earth must be very accurately timed, relative to a system-wide master clock. Furthermore, the devices that initiate the seismic signals must likewise be very accurately timed according to the same master clock reference. Generally acceptable timing accuracy is on the order of 50-100 microseconds, although accuracy as low as 1 millisecond can be tolerated in some circumstances. Less accurate timing can result in signal degradation in the various stages of processing to which the measured seismic reflections are subsequently subjected. The ultimate goal, to image the subsurface geologic layers, may be severely compromised by errors in timing accuracy of the recorded data.  
         [0011]     A seismic data acquisition system may have many thousands of arrays of transducers (termed seismic sensor arrays) in contact with the earth with all of them being simultaneously measured and recorded. Many thousands of such recordings, each with a different seismic source location, are made during the course of a single 3D seismic survey. All of the recorded data may be combined in the imaging process. Difficulties in guaranteeing accurate timing arise due to the wide geographic dispersal of the seismic sensor arrays, often over varying and difficult terrain. The seismic sources are also positioned widely and initiated once for each recording, thus many thousands of times during the course of a typical survey project. The distances and obstacles separating the seismic receivers and sources make the synchronization of these seismic survey system elements very challenging.  
         [0012]     It would thus be desirable to have a synchronization method and suitable equipment and software that could be used under a very wide range of conditions, including both wired and wirelessly connected network elements, to provide highly accurate and reliable synchronization of both seismic receivers and seismic sources in a networked total system. Such a system has been invented and is described in the remainder of this document.  
       BRIEF SUMMARY OF THE INVENTION  
       [0013]     It is therefore an object of the invention to provide methods and apparatus for improved synchronization of seismic data acquisition through utilization of a master clock, one or more high-precision clocks distributed in a wired or wireless network of seismic data acquisition devices and seismic source devices, and other less precise clocks located elsewhere in the network, wherein the methods of utilization are varied and summarized as described herein.  
         [0014]     It is a further object of the invention to utilize time signals from a global positioning system (GPS) or a radio beacon system to replace or supplement the role of the master clock and/or high precision clocks in the network of data acquisition devices and seismic source devices, thereby providing improved synchronization.  
         [0015]     It is another object of the invention to provide an improved method of synchronizing clocks to the master clock, to a high precision clock or to an adjacent clock of less precision by utilizing known transmission delay distributions for the portion of the network between the reference clock and the clock to be synchronized. According to this aspect of the invention the transmission delay characteristics for the germane transmission path may be measured or derived a priori and stored with the device that controls the clock to be synchronized. Then delay patterns of repeated synchronization signals are statistically characterized and may be compared to the stored characterization patterns. An improved synchronization is thereby facilitated.  
         [0016]     The methods of the invention may be applied whether the network elements are in communication through wired or wireless means such as but not limited to radio, conductive cable, fiber optic cable, seismic signaling and other means.  
         [0017]     According to one aspect of the invention, seismic source events may be triggered at scheduled times or at random times but at times synchronized with greater accuracy using one or more methods and/or the apparatus of the invention.  
         [0018]     A further aspect of the invention provides a method of synchronizing high precision clocks to the master clock by bringing them in close proximity and connecting them either physically or through short wireless transmission paths in order to synchronize, then placing them in their remote locations within the seismic network.  
         [0019]     The invention includes a method of time-stamping data by a higher-precision clock before transmission of data to a device containing another clock further distributed in the network there by facilitating improvement in synchronization by shared reliance on the accuracy of the high-precision clock.  
         [0020]     According to one aspect of the invention, the seismic network may include a high-speed backbone connecting lower speed branches to a central point wherein the backbone has less transmission delay and a tighter statistical distribution of transmission times enabling better synchronization of the clocks connected to the backbone.  
         [0021]     All aspects of the invention may contribute to the better synchronization of seismic sources and/or of the recording of seismic data by the receivers, enabling improved seismic imaging of the earth&#39;s subsurface.  
         [0022]     Additional objects and advantages of the invention will become apparent to those skilled in the art upon reference to the detailed description taken in conjunction with the provided figures. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0023]     The advantages and further aspects of the invention will be readily appreciated by those of ordinary skill in the art as the same becomes better understood by reference to the following detailed description when considered in conjunction with the accompanying drawings in which like reference characters designated like or similar elements throughout.  
         [0024]      FIG. 1  is a schematic representation of a typical seismic survey field layout.  
         [0025]      FIG. 2  is a schematic representation of a seismic survey field layout combining wired and wireless connections between various network elements and incorporating features of the preferred embodiment.  
         [0026]      FIG. 3  is a schematic drawing of a high precision clock module according to the present invention.  
         [0027]      FIG. 4  is a schematic drawing of a wireless data acquisition module (RAM) according to the present invention.  
         [0028]      FIG. 5  is a time line representation of the repeated transmission of synchronization signals showing statistical spreading of reception intervals and determination of clock drift. 
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0029]     For reference, a typical seismic survey grid is shown schematically by  FIG. 1  to include a large number of remote acquisition modules (RAMs)  100  having orderly connections along receiver lines  120  to respective line tap units  140 . Line tap units (LTUS)  140  connect receiver lines  120  to base lines  160 . The base lines  160  connect ultimately to the central recording unit (CRU)  180 . Jumpers  170  connect ends of receiver lines  120  to form loops. RAMs  100  perform functions of collecting seismic sensor array signals, digitizing these signals if they are not already digitized within the arrays, and transmitting the data toward the CRU  180 . Also the RAMs  100  receive communications originated by the CRU  180  and by more remote RAMs  100  and relaying this information to adjacent RAMs  100  or LTUs  140 .  
         [0030]     Seismic sensors are connected to the RAMs  100  and may be of one or more types of transducers such as geophones or hydrophones. Sensor arrays may range from single sensors to multiple sensors in geometrical arrays, combined to form one or more signal channels per RAM.  
         [0031]     Specialized seismic sources create the seismic waves that travel into the subsurface and reflect upward to the surface where they are detected by the seismic sensor arrays connected to the RAMs  100 . The various RAMs, receiver lines, LTUs, base lines, jumpers and CRU perform as a seismic communications network, and also as a seismic data acquisition system, according to the commands emanating from the CRU  180 .  
         [0032]     Receiver line segments and base line segments may be physically realized by employment of sections of cable. The cable may contain electrical conductors or optical fibers (of a combination thereof) to carry signals in both directions, logically toward or away from the CRU  180 .  
         [0033]     Alternatively radio or light wave communications may replace the conventional cable sections connecting the various modules shown in  FIG. 1  so that cables are not required for communication yet are still required for connecting seismic sensor arrays to the RAMs  100 .  
         [0034]      FIG. 2  provides a map view schematic diagram of.a seismic data acquisition network system so configured and with additional capabilities according to the preferred embodiment of the present invention, with wireless RAMs  230  situated wherever it is more convenient to bypass obstacles using wireless connections. Point-to-point wireless links  250  may likewise be utilized to bypass obstacles along the base line. A combination of wired and wireless network elements makes up the hybrid total network. Wireless network elements may also retain the capability to communicate via conventional cable circuits to add flexibility to network implementation.  
         [0035]     Source event generators  200  are actuated under control of the CRU&#39;s  180  control electronics  210  according to the dictates of the human operator. The various cable sections and modules, as well as the control electronics  210 , a component of the CRU  180 , may be frequently repositioned during the course of the seismic survey. The area of the survey may be water-covered, even to depths in excess of 100 m, partially submerged or wholly dry land. Therefore the operator wishes to have reliable and robust equipment that can be readily reconfigured for each new physical location and position within the network, and be readily and reliably synchronized under these diverse conditions.  
         [0036]     Commands and data emanating from a central point in the network, more specifically the control electronics  210  in the CRU  180  ( FIG. 2 ), travel from the originating point along the provided wired or wireless transmission pathways to the adjacent network modules. These network modules may be LTUs ( 140 ), high speed LTUs ( 220 ), point-to-point wireless links ( 250 ) or RAMs ( 100  if not capable of wireless data transmission, or  230 , if capable of wireless) in proximity to the CRU  180 . The commands and data are relayed from there to the next adjacent network module. This process continues from modules nearer to the CRU  180  to adjacent modules which are one step further from the CRU  180 , and so on, until the furthermost modules in the network receive the commands and data. (“adjacent” or “in proximity” here means “logical proximity” in a network definition sense. Physical position may not conform exactly to the descriptors “adjacent” or “in proximity” in a network sense.)  
         [0037]     The networked LTUs and RAMs are designed to receive commands and data from a neighboring RAM or LTU on one physical side, and retransmit the command or data to a neighboring RAM on its other physical side. In this fashion commands and data can reach all RAMs in the network. The length of time it takes commands or data to travel from the CRU  180  to any particular RAM in the network is not entirely predictable. Every time one RAM repeats another modules commands or data, a small but significant timing uncertainty is added to the propagation time of the command or data. This timing uncertainty limits the degree to which RAMs (and LTUs) can be synchronized. In prior art systems this in turn results in sensor arrays being measured at the wrong instants in time.  
         [0038]     Data acquisition modules and inter-connecting networks of many designs and types are available in the industry, but they all suffer from problems of unreliable synchronization or poor synchronization accuracy under some conditions. The unique features of the present invention, described in the remainder of this section, overcome these limitations.  
         [0039]     The network shown in Fig. 2  embodies other innovations relative to the network in  FIG.1 . that are of paramount importance in the present invention. These innovations include the distributed high precision clock modules  240 , source event generators  200 , wireless capability, GPS capability and also the high-speed backbone  225  and high speed LTUs  220 . For example, this high-speed backbone may be a fiber-optic linkage. It is designed to have greater bandwidth and smaller communication delays than that of the receiver lines  120  and their LTUs  140 . Nevertheless, a small delay will be characteristic of each element of the high speed backbone.  
         [0040]     To facilitate solution of the synchronization problem, a network master clock  260  and one or more additional high precision clock modules  240  are added to the network of RAMs. The master clock  260  is typically based on a high precision oscillator circuit such as an OCXO (Oven Controlled Crystal Oscillator) device capable of a very high precision such as 0.001 PPM. The master clock  260  also contains a GPS module  340  as do the high precision clock modules  240 . The master clock  260  may be of identical design to the high precision clock modules  240  or it may contain features that provide even higher precision. It may also be equipped to receive local, regional or global radio signals containing highly precise time signals. Utilizing time-stamping of information transmitted outwards in the network from the CRU  180 , the high precision clock modules  240  correct for the timing uncertainty associated with the propagation of commands and data throughout the network. The high precision clock modules  240  can take various forms and can be located internally or externally to the RAMs and LTUs. In  FIG. 2  an internal high precision clock module  245  is shown internal to a wireless RAM  230 , in the lower left part of the diagram.  
         [0041]      FIG. 3  is a schematic drawing of the high precision clock module  240 . In one application, the high precision clock module  240  relies solely on the high precision clock  300  for its time keeping (after synchronization to the master clock  260 ). If the GPS module  340  is utilized, however, both the high precision clock and the GPS module  340  are utilized together in time keeping. In another mode, the radio beacon signals instead of GPS time signals are utilized together with the high precision clock. The high precision clock  300  is typically based on a high precision oscillator capable of time keeping with errors 0.001 PPM. In another embodiment, the high precision clock possesses an oscillator of lower precision, such as 0.5 PPM, but in this case the high precision clock module  240  relies on the GPS module or radio beacon signals to attain high precision. In this embodiment the highly precise GPS time signals or radio beacon signals are used to continually correct the drift of the less precise clock, and in this way the high precision clock module  240  does achieve high precision.  
         [0042]     The high precision clock module  240  includes a RAM interface  310  enabling it to be connected to a wireless RAM  230 . A wired clock interface and synchronization module  320  connected to a high precision clock wired linkage  390  provides a means for physical connection to another high precision clock module for purposes of synchronization. A wireless clock interface and synchronization module  330 , utilizing radio beacon signals received through high precision clock wireless linkage  395 , provides a parallel capability for synchronization without physical connection to another module. In another mode, GPS antenna  370  connects to GPS module  340  providing a means of receiving and processing GPS signals useful for positioning as well as precise synchronization. Seismic event controller  360  and event controller linkage  380  provide a means to communicate with source event generators  200 . This linkage may be wired or wireless. Controlling the other modules and responsible for the primary time-keeping, synchronization and communication functions of the high precision clock module  240  is the DSP controller and timer  350 .  
         [0043]      FIG. 4  is a schematic drawing of a wireless data acquisition module (RAM  230 ) according to the preferred embodiment. The analog, analog-to-digital circuitry and test circuitry  420  provides the functionality for converting the analog signals from one or more seismic sensor arrays  425  containing the seismic sensors  270  comprising geophones and/or hydrophone transducers. This circuitry  420  is connected to the DSP controller  410  that also interfaces to the other principle components of the RAM  230  and controls their functions. An internal clock  400  contains a TCXO (Temperature Compensated Crystal Oscillator) or equivalent oscillator circuit with time-keeping precision on the order of 0.5 PPM. The RAM  230  optionally includes an internal high precision clock module  245 . In the preferred embodiment this module  245  contains a GPS module  340  and an oscillator circuit that may be based on a TCXO oscillator with precision such as 0.5 PPM, less precise than an oscillator that might be used in an external high precision clock module  240 , and also requiring less power, a critical design factor for the RAM  230 . GPS antenna  460  provides a means of receiving GPS signals which are processed by the GPS module  340  within the internal high precision clock module  245 . Clock antenna  465  provides for reception of radio signals from a project local, regional or global beacon containing precise timing information. These signals are also processed within the internal high precision clock module  245 . Two further external linkages to the internal high precision clock module  245  are the wired high precision clock linkage—for use if the RAM  230  is to be connected with an external high precision clock module—and a linkage  475  that connects to a source event generator  200 .  
         [0044]     A mobile clock module interface  430  and linkage to a mobile clock  435  provide a facility for rapid temporary connection of the RAM  230  to a high precision clock module  240  for purposes of synchronizing the RAM internal clock  400  and/or the optional internal high precision clock module  245 .  
         [0045]     In  FIG. 4 a  wireless transceiver radio  440  is controlled by the DSP controller  410  for purposes of network communication. Antenna  445  connects to the wireless transceiver radio  440 . Communication module  450  is also connected to DSP controller  410  and provides a second means of communicating: by conventional wired network linkage. Communication linkage  452  connects to the previous network device (nearer to CRU  180  in a network sense) and communication linkage  454  connects to the next network device along the cable (further from the CRU  180 ).  
         [0046]     The process of synchronizing the entire network, including all LTUs and RAMs, to the Master Clock  260  is undertaken just prior to the beginning of a period of seismic data acquisition and frequently thereafter, as is necessary to maintain a desired accuracy of synchronization. Synchronization of the network is done in two stages, first synchronization of the high precision clocks throughout the network, and subsequently, synchronization of the remainder of the clocks. Each LTU ( 140  or  220 ) and RAM  230  that does not possess a high precision clock module ( 240  or  245 ) will have its clock synchronized in the second stage. After the second stage of synchronization, the accuracy of sample times of the seismic sensor array data by the RAMs will be within the desired limits of accuracy.  
         [0047]     Clock drift is a continuous process, so it is necessary to periodically synchronize. Synchronization may done on a frequent and regular planned schedule, known to all the RAMs  230  and LTUs ( 140 or  220 ). Synchronization signals may originate from the device having access to the Master Clock  260 , normally the CRU  180 . Synchronizing may include both of the two stages, i.e. first the high precision clocks, secondly the remainder of the clocks, or synchronization may include only the stage two of the process (if only Stage 2 is performed, it is necessary to have performed a Stage 1 synchronization at some previous time). In this simplified resynchronization (stage two only) the high precision clocks are relied upon as standards for regions of the network in their proximity. A more efficient resynchronization is made possible due to reliance on the distributed high precision clocks.  
         [0048]     Three different mechanisms to synchronize or calibrate the high precision clocks, as required in the first stage of network synchronization, are described next. These methods are 1) Synchronizing Clocks before deployment, 2) Synchronizing Clocks after deployment though Direct Transmission, and 3) Synchronizing Clocks after deployment though Repeated Transmission.  
         [0049]     (1) Synchronizing High Precision Clocks Before Deployment:  
         [0050]     Before the high precision clock modules,  240  and  245 , are deployed throughout the network, they are brought to a central location and synchronized. The high precision clocks, whether external or internal to the RAMs  230  are each directly connected through wires or a short distance wireless medium (such as optics) to a (single) master clock  260  and calibrated or synchronized. Once calibrated or synchronized, the clock can be used to provide very accurate timing information to any device connected to the clock either through a wired or wireless medium. The purpose of connecting the clock to the master clock through only wires or a short distance wireless medium is to prevent or minimize any addition of timing uncertainty that an intermediary device might add in calibrating or synchronizing the master high precision clock with another high precision clock. Once synchronized, the high precision clocks are deployed and connected to devices in the network.  
         [0051]     (2) Synchronizing Clocks After Deployment Through Direct Transmission:  
         [0052]     Unsynchronized high precision clock modules  240  are first connected to specific RAMs  230  in the network and a timing signal is transmitted to them and to the internal high precision clock modules  245  which serves to synchronize all of them to the master clock  260 .  
         [0053]     The wireless medium synchronization can be done in three different ways: 
        a) The high precision clock modules  240  and  245  and master clock  260  can be designed to receive the very accurate timing information transmitted from the Global Positioning System (GPS), a series of satellites, which orbit the earth. The GPS timing information can be used to continually keep the master clock  260  and the high precision clock modules ( 240  and  245 ) synchronized. Other satellite networks may provide equivalent timing information and may be utilized instead of the GPS.     b) The high precision clock modules  240  and  245  can be designed to receive a radio signal transmitted from a centrally located master clock  260  which is brought on site. The radio signal transmitted from the master clock is designed to reach all the high precision clock modules.     The radio signal is used to synchronize all the high precision clocks to the master clock.     c) The master clock  260  and the high precision clock modules  240  and  245  can be designed to receive a radio signal transmitted regionally or worldwide that provides a sufficiently accurate timing reference.     ( 3 ) Synchronizing Clocks After deployment Through Repeated Synchronization Transmissions:        
 
         [0059]     In most cases, the propagation uncertainty resulting from the rebroadcast of synchronization signals, commands, and data has a known statistical distribution, or a distribution that can be determined in advance, which can be exploited to improve the synchronization of the RAMs  230  in the network. To begin with, both a definite upper and a lower limit can be set on the propagation time of the signals. The uncertainty of the propagation time can be either: 
        a) Uniformly Random: any delay is equally likely as long as it is greater then a minimum propagation time and less then a maximum propagation time. If both RAMs  230  know the predetermined times and intervals, then as the first RAM transmits synchronization signals, the second RAM is able use its internal clock to find a moment where 50% of the synchronization signals come before that moment and 50% of the synchronization signals come after that moment. That moment will be predetermined transmission time plus the midway interval between the minimum and maximum propagation times.     b) Weighted: any delay between a minimum and a maximum value is possible with certain delays more likely than others. 
            Any delay must be greater than a minimum propagation time and less then a maximum propagation time. The statistical distribution of the propagation times is calculated in a controlled environment meant to match the environment in which the RAMs  230  are to be used. The statistical distribution is programmed into all the RAMs to be used at a later date. The statistical distribution is dependent on the physical environment, the properties of the electronics in RAMs, and the firmware controlling the functioning of the RAMs. When the RAMs attempt to synchronize themselves in actual use, the first RAM transmits a synchronization signal to a second RAM which will use the synchronization signal and prior knowledge of the propagation statistical distribution to synchronize its clock to the first RAM. The first RAM will send synchronization signals to the second RAM at the same frequency and interval as was done in the controlled environment in which the propagation statistical distribution was determined. Using its internal clock, the second RAM will measure the interval between when it expected to receive the synchronization signal and when it actually received the synchronization signal. This interval is known as the reception interval. The second RAM will match that pattern of reception intervals with the pattern of reception intervals stored inside the second RAM. The more synchronization signals the second RAM receives from the first RAM, the more accurately the second RAM can match the reception interval pattern to the known reception interval pattern. The goal is to receive enough reception intervals to match a specific reception interval with the previously determined reception interval pattern. Once a match to the pattern is found, the second RAM, knowing the transmission time delay from the first RAM to the second RAM, will be able to determine the drift of its internal clock  400 .    
               
 
         [0063]     The second RAM can reset its internal clock to be synchronized with the first RAM&#39;s clock by accounting for the known time delay of the propagation signal.  
         [0064]     Each RAM  230  in the network can also use this method (in the stage two of the synchronization process) starting from a synchronized high precision clock module  240  or  245  which synchronizes the adjacent RAMs, which in turn synchronize their adjacent RAMs, until all the RAMs in the network are synchronized.  
         [0065]     Synchronizing RAMs Without a High Precision Clock Module to the RAMs With a High Precision Clock:  
         [0066]     The control electronics  210  of the CRU  180  transmit synchronization signals on to the network to which all RAMs  230  synchronize. Each RAM receives the synchronization signal from a neighboring RAM  230  or LTU ( 140  or  220 ) on one physical side of the device and rebroadcasts the synchronization signal to another neighboring RAM or LTU on its other physical side. In this way, the synchronizing signal travels to all the devices connected to the network. The act of re-broadcasting the synchronization signal adds a small, but significant uncertainty to the propagation time of the synchronization signal as it travels throughout the network. Included in the synchronization signal is a timestamp. The timestamp contains the best estimate of the time of initiation of the original synchronization signal according to the master clock  260 . The timestamp is used to set each RAM&#39;s internal clock  400  to the same moment after adjusting for expected propagation time. Because of the uncertainty added in the propagation time of the synchronization signal, the propagation time can&#39;t be perfectly accounted for when adjusting the RAMs internal clock  400 . As the synchronization signal travels throughout the network, it encounters RAMs with a high precision clock module ( 240  or  245 ) which have been synchronized with the master clock  260 . Each RAM  230  with a high precision clock module replaces the timestamp that it receives from the neighboring RAM with a more accurate timestamp that it generates, such that the more accurate timestamp is a better estimate of the true time that the synchronization signal originated at the master clock  260 . It then sends the synchronization signal with the new timestamp to its neighbor just as it would have if it didn&#39;t have a high precision clock. In this manner, the degree of uncertainty of the synchronization can be reduced to the uncertainty of the high precision clock plus the uncertainty that each RAM without a high precision clock adds to the synchronization time. For instance, if a RAM is 5 re-broadcasts away from a high precision clock, then only the added uncertainty of retransmitting the synchronization signal 5 times plus the uncertainty of the high precision clock effects the synchronization of that RAM.  
         [0067]      FIG. 5  illustrates the method of synchronizing using repeated transmissions. For illustration only five scheduled transmissions are used. RAM-X transmits synchronization signals to RAM-Y over the communication channel. The communication channel may be wired or wireless and may have intervening network devices which receive and re-transmit the synchronization signals. In any case, RAM-Y possesses a Reception Interval Distribution Model which provides it with the expected behavior of the communication linkage in terms of probabilistic distribution of reception intervals. In this example the model is a uniform distribution from DeltaT to 3 DeltaT, where DeltaT is 0.5 times the interval between scheduled synchronization signals. The actual times of receipt, according to RAM-Y&#39;s clock are shown next. The five signals are spread uniformly from 2 DeltaT to 4 DeltaT. This is in perfect conformance with the model, except there is a shift of 1 DeltaT to the right. RAM-Y therefore computes that its internal clock lags RAM-X&#39;s clock by 1 DeltaT. RAM-Y completes the synchronization to RAM-X&#39;s clock by setting its own internal clock back by 1 DeltaT. This example is simplified by showing a perfect match of the actual reception intervals to the model. If the match is not perfect in practice, RAM-Y will perform a best-fit computation to optimize the synchronization as best it can.  
         [0068]     Seismic Event Generation and Synchronization:  
         [0069]     With seismic recording, a seismic event is needed to induce a seismic signal into the earth, which then reflects, refracts, and diffracts from the subsurface layers of the earth and eventually is picked up by the transducers planted in the earth. The seismic event for instance could be a dynamite explosion, or a mechanical device, which induces a signal into the earth. The seismic event generator  200  needs to be synchronized with the deployed RAMs  230  which measure the seismic signals created by the seismic event. The synchronization of the RAMs with the seismic event generator can be done with the use of the high precision clock modules  240 . A seismic event generator  200  may simply connect to a RAM  230  which has the ability to trigger the seismic event generator to produce a seismic event. Also, the seismic event generator may have either an internal or external high precision clock module ( 245  or  240 ) whose function it is to trigger the seismic event generator at predetermined moments in time when all the RAMs are synchronized and are measuring the seismic signals picked up by the seismic sensors  270 . The synchronization of the internal or external clock module which is connected to the seismic event generator is to be done in one of the three methods described, namely: 1) Synchronizing Clocks before deployment, 2) Synchronizing Clocks after deployment though Direct Transmission, and 3) Synchronizing Clocks after deployment though Repeated Transmission.  
         [0070]     Recording of Seismic Signals:  
         [0071]     Once all the RAMs  230  are synchronized, they are programmed to start measuring the seismic sensors  270  at a specific time of day or to start measuring them after a programmed delay. The synchronized RAMs can use an internal clock  400  to continue to measure the transducers at the appropriate moments. Each RAMs internal clock may need to be periodically re-synchronized with the rest of the RAMs in the network using one of the three methods described, namely: 1) Synchronizing Clocks before deployment, 2) Synchronizing Clocks after deployment though Direct Transmission, and 3) Synchronizing Clocks after deployment though Repeated Transmission. The times that the RAMs need to be re-synchronized will be dependent on drift of the oscillators relative to each other and the needed seismic sensor array measurement precision.  
         [0072]     The recorded data may be stored in memory at the originating RAM. 230  It may also be transmitted via intervening network elements or directly to the CRU  180 . Before reaching the CRU it may be temporarily stored in another RAM or LTU ( 140  or  220 ). Because data packets are either explicitly or implicitly time-stamped by the originating RAM with the best estimate of the master clock time at which the samples were taken, no further synchronization errors can occur during this transmission and data compilation phase of the seismic data acquisition process.  
         [0073]     Although our invention has been described in terms of specified embodiments which are set forth in detail, it should be understood that this is by illustration only and that the invention is not necessarily limited thereto. Alternative embodiments and operating techniques will become apparent to those of ordinary skill in the art in view of the present disclosure. Accordingly, modifications of the invention are contemplated which may be made without departing from the spirit of the claimed invention.