A method of establishing wireless communications between an interrogator and individual ones of multiple wireless identification devices, the method comprising utilizing a tree search method to establish communications without collision between the interrogator and individual ones of the multiple wireless identification devices, a search tree being defined for the tree search method, the tree having multiple levels representing subgroups of the multiple wireless identification devices, the number of devices in a subgroup in one level being half of the number of devices in the next higher level, the tree search method employing level skipping wherein at least one level of the tree is skipped. A communications system comprising an interrogator, and a plurality of wireless identification devices configured to communicate with the interrogator in a wireless fashion, the respective wireless identification devices having a unique identification number, the interrogator being configured to employ a tree search technique to determine the unique identification numbers of the different wireless identification devices so as to be able to establish communications between the interrogator and individual ones of the multiple wireless identification devices without collision by multiple wireless identification devices attempting to respond to the interrogator at the same time, wherein levels of the tree are occasionally skipped. rfid tags are managed by an interrogator. In one embodiment, the interrogator sends a first command indicating a first value and a first memory range, and a second command indicating second value and a second memory range. The first memory range differs from the second memory range by at least two bits. rfid tags compare the first and second values to corresponding values stored in the tags to determine if the tags are selected. Selected tags may respond to the interrogator with independently generated random numbers.
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1. A method of establishing wireless communications between an interrogator and wireless identification devices, the method comprising utilizing a tree search technique to establish communications without collision between the interrogator and individual ones of the multiple wireless identification devices, the method including using a binary search tree having multiple levels representing subgroups of the multiple wireless identification devices, the number of devices in a subgroup in one level being less than the number of devices in the next level, the tree search technique employing level skipping wherein every second level of the tree is skipped.
0. 39. A method performed by an interrogator, comprising:
transmitting a first command to select a group of rfid devices based, at least in part, on a first memory range beginning at a first bit location;
transmitting a second command, successively following the first command, to select a subgroup of the group of rfid devices based, at least in part, on a second memory range beginning at a second bit location, wherein the second bit location is shifted by two or more bits from the first bit location; and
receiving a reply from at least one rfid device of the subgroup of rfid devices, the reply including a random number generated by the rfid device.
0. 55. A system comprising:
an rfid reader configured to send a first command to indicate a first bit string and a first range of bits, followed, without any intervening query commands, by a second command to indicate a second bit string and a second range of bits, wherein the first range of bits differs from the second range of bits by at least two bits;
an object associated with an identification code; and
an rfid tag affixed to the object and storing the identification code, the rfid tag configured to compare the first bit string to a first value stored in memory corresponding to the first range of bits, to compare the second bit string to a second value stored in memory corresponding to the second range of bits, to backscatter a self-generated random number, and to backscatter the identification code.
0. 31. A method, comprising:
sending a first command followed by a second command, absent any intervening commands, to a plurality of rfid devices, wherein the first command comprises first and second radio frequency (RF) signals and the second command comprises third and fourth RF signals;
receiving a reply from at least one rfid device, the reply indicating that a first number stored in a memory of the rfid device bounded at a first location indicated by the first RF signal is equal to a first value indicated by the second RF signal, and a second number stored in the memory of the rfid device bounded at a second location indicated by the third RF signal is equal to a second value indicated by the fourth RF signal, the reply including a random number independently generated by the rfid device, wherein the second location is offset by two or more bits from the first location in the memory of the rfid device.
6. A method of addressing messages from an interrogator to a selected one or more of a number of communications devices, the method comprising:
establishing for respective devices unique identification numbers:
causing the devices to select random values, wherein respective devices choose random values independently of random values selected by the other devices;
transmitting a communication, from the interrogator, requesting devices having random values within a specified group of random values to respond;
receiving the communication at multiple devices, devices receiving the communication respectively determining if the random value chosen by the device falls within the specified group and, if so, sending a reply to the interrogator; and
determining using the interrogator if a collision occurred between devices that sent a reply and, if so, creating a new, smaller, specified group, using a search tree, that is one quarter of the first mentioned specified group, wherein at least one level of a search tree is skipped.
22. A system comprising:
an interrogator;
a number of communications devices capable of wireless communications with the interrogator;
means for establishing for respective devices unique identification numbers respectively having the first predetermined number of bits;
means for causing the devices to select random values, wherein respective devices choose random values independently of random values selected by the other devices;
means for causing the interrogator to transmit a command requesting devices having random values within a specified group of random values to respond;
means for causing devices receiving the command to determine if their chosen random values fall within the specified group and, if so, to send a reply to the interrogator; and
means for causing the interrogator to determine if a collision occurred between devices that sent a reply and, if so, to create a new, smaller, specified group that is one quarter of the first mentioned specified group, wherein at least one level of the tree is skipped.
11. A method of addressing messages from a transponder to a selected one or more of a number of communications devices, the method comprising:
causing the devices to select random values, wherein respective devices choose random values independently of random values selected by the other devices;
transmitting a communication, from the transponder, requesting devices having random values within a specified group of a plurality of possible groups of random values to respond, the specified group being less than or equal to the entire set of random values, the plurality of possible groups being organized in a binary tree having a plurality of levels, wherein groups of random values decrease in size with each level descended;
devices receiving the communication respectively determining if the random value chosen by the device falls within the specified group and, if so, sending a reply to the transponder; and, if not, not sending a reply; and
determining using the transponder if a collision occurred between devices that sent a reply and, if so, creating a new, smaller, specified group by descending at least two levels in the tree.
0. 48. A method, comprising:
providing an rfid device affixed to an object to identify the object, the rfid device storing an identification number;
sending a first command from an interrogator, the first command configured to select a group of rfid devices based, at least in part, on a respective first value stored in each respective rfid device of the group of rfid devices, the respective first value bounded at a respective first bit location within a memory of the respective rfid device;
sending a second command from the interrogator after sending the first command and before sending any intervening command from the interrogator, the second command configured to select a subgroup of the group of rfid devices based, at least in part, on a respective second value stored in the respective rfid device of the group of rfid devices, the respective second value bounded at a respective second bit location within the memory of the respective rfid device, wherein the second bit location is at least two bits away from the first bit location; and
receiving a random number from the rfid device, the rfid device belonging to the subgroup, the random number independently generated by the rfid device and being separate from the identification number.
0. 27. A method, comprising:
sending a first command from an interrogator to a plurality of rfid devices, the first command comprising a first set of fields, wherein the first set of fields includes a first bit string and describes a first memory range that starts at a first bit location;
receiving the first command by an rfid device of the plurality of rfid devices, and in response, the rfid device comparing the first bit string to a first value stored in a first portion of a memory of the rfid device corresponding to the first memory range;
sending a second command from the interrogator to the plurality of rfid devices successively following the first command, the second command comprising a second set of fields, wherein the second set of fields includes a second bit string and describes a second memory range that starts at a second bit location offset from the first bit location by two or more bits;
receiving the second command by the rfid device, and in response, the rfid device comparing the second bit string to a second value stored in a second portion of the memory of the rfid device corresponding to the second memory range; and
receiving a reply from the rfid device based, at least in part, on a first result from the comparing of the first bit string to the first value, and on a second result from the comparing of the second bit string to the second value, wherein the reply includes a random number generated by the rfid device.
16. A method of addressing messages from an interrogator to a selected one or more of a number of rfid devices, the method comprising:
establishing for respective devices unique identification numbers:
causing the devices to select random values, wherein respective devices choose random values independently of random values selected by the other devices;
transmitting from the interrogator a command requesting devices having random values within a specified group of a plurality of possible groups of random values to respond, the specified group being less than or equal to the entire set of random values, the plurality of possible groups being organized in a binary tree having a plurality of levels, wherein groups of random values decrease in size with each level;
receiving the command at multiple of the devices, the devices receiving the command respectively determining if the random value chosen by the device falls within the specified group and, only if so, sending a reply to the interrogator, wherein sending a reply to the interrogator comprises transmitting both the random value of the device sending the reply and the unique identification number of the device sending the reply;
determining using the interrogator if a collision occurred between devices that sent a reply and, if so, creating a new, smaller, specified group using a level of the tree different from the level used in the interrogator transmitting, wherein at least one level of the tree is skipped, the interrogator transmitting a command requesting devices having random values within the new specified group of random values to respond; and
if a reply without collision is received from a device, the interrogator subsequently sending a command individually addressed to that device.
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devices receiving the command respectively determining if their chosen random values fall within the new smaller specified group and, if so, sending a reply to the interrogator.
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determining if a collision occurred between devices that sent a reply and, if so, creating a new specified group and repeating the transmitting of the command requesting devices having random values within a specified group of random values to respond using different specified groups until all of the devices within communications range are identified.
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and now U.S. Pat. No. 6,130,603. Other embodiments are possible. A power source 18 is connected to the integrated circuit 16 to supply power to the integrated circuit 16. In one embodiment, the power source 18 comprises a battery. The device 12 further includes at least one antenna 14 connected to the circuitry 16 for wireless or radio frequency transmission and reception by the circuitry 16.
The device 12 transmits and receives radio frequency communications to and from an interrogator 26. An exemplary interrogator is described in commonly assigned U.S. patent application Ser. No. 08/907,689, filed Aug. 8, 1997 and now U.S. Pat. No. 6,289,209, which is incorporated herein by reference. Preferably, the interrogator 26 includes an antenna 28, as well as dedicated transmitting and receiving circuitry, similar to that implemented on the integrated circuit 16.
Generally, the interrogator 26 transmits an interrogation signal or command 27 via the antenna 28. The device 12 receives the incoming interrogation signal via its antenna 14. Upon receiving the signal 27, the device 12 responds by generating and transmitting a responsive signal or reply 29. The responsive signal 29 typically includes information that uniquely identifies, or labels the particular device 12 that is transmitting, so as to identify any object or person with which the device 12 is associated.
Although only one device 12 is shown in
The radio frequency data communication device 12 can be included in any appropriate housing or packaging. Various methods of manufacturing housings are described in commonly assigned U.S. patent application Ser. No. 08/800,037, filed Feb. 13, 1997, and now U.S. Pat. No. 5,988,510, which is incorporated herein by reference.
If the power source 18 is a battery, the battery can take any suitable form. Preferably, the battery type will be selected depending on weight, size, and life requirements for a particular application. In one embodiment, the battery 18 is a thin profile button-type cell forming a small, thin energy cell more commonly utilized in watches and small electronic devices requiring a thin profile. A conventional button-type cell has a pair of electrodes, an anode formed by one face and a cathode formed by an opposite face. In an alternative embodiment, the power source 18 comprises a series connected pair of button type cells. Instead of using a battery, any suitable power source can be employed.
The circuitry 16 further includes a backscatter transmitter and is configured to provide a responsive signal to the interrogator 26 by radio frequency. More particularly, the circuitry 16 includes a transmitter, a receiver, and memory such as is described in U.S. patent application Ser. No. 08/705,043, filed Aug. 29, 1996 and now U.S. Pat. No. 6,130,602.
Radio frequency identification has emerged as a viable and affordable alternative to tagging or labeling small to large quantities of items. The interrogator 26 communicates with the devices 12 via an RF link, so all transmissions by the interrogator 26 are heard simultaneously by-all devices 12 within range.
If the interrogator 26 sends out a command requesting that all devices 12 within range identify themselves, and gets a large number of simultaneous replies, the interrogator 26 may not be able to interpret any of these replies. Therefore, arbitration schemes are provided.
If the interrogator 26 has prior knowledge of the identification number of a device 12 which the interrogator 26 is looking for, it can specify that a response is requested only from the device 12 with that identification number. To target a command at a specific device 12, (i.e., to initiate point-on-point communication), the interrogator 26 must send a number identifying a specific device 12 along with the command. At start-up, or in a new or changing environment, these identification numbers are not known by the interrogator 26. Therefore, the interrogator 26 must identify all devices 12 in the field (within communication range).such as by determining the identification numbers of the devices 12 in the field. After this is accomplished, point-to-point communication can proceed as desired by the interrogator 26.
Generally speaking, RFID systems are a type of multiaccess communication system. The distance between the interrogator 26 and devices 12 within the field is typically fairly short (e.g.. several meters), so packet transmission time is determined primarily by packet size and baud rate. Propagation delays are negligible. In RFID systems, there is a potential for a large number of transmitting devices 12 and there is need for the interrogator 26 to work in a changing environment, where different devices 12 are swapped in and out frequently (e.g.. as inventory is added or removed). In such systems, the inventors have determined that the use of random access methods work effectively for contention resolution (i.e.. for dealing with collisions between devices 12 attempting to respond to the interrogator 26 at the same time).
RFID systems have some characteristics that are different from other communications systems. For example, one characteristic of the illustrated RFID systems is that the devices 12 never communicate without being prompted by the interrogator 26. This is in contrast to typical multiaccess systems where the transmitting units operate more independently. In addition, contention for the communication medium is short lived as compared to the ongoing nature of the problem in other multiaccess systems. For example, in a RFID system, after the devices 12 have been identified, the interrogator can communicate with them in a point-to-point fashion. Thus, arbitration in a RFID system is a transient rather than steady-state phenomenon. Further, the capability of a device 12 is limited by practical restrictions on size, power, and cost. The lifetime of a device 12 can often be measured in terms of number of transmissions before battery power is lost. Therefore, one of the most important measures of system performance in RFID arbitration is total time required to arbitrate a set of devices 12. Another measure is power consumed by the devices 12 during the process. This is in contrast to the measures of throughput and packet delay in other types of multiaccess systems.
Three variables are used: an arbitration value (AVALUE), an arbitration mask (AM ASK), and a random value ID (RV). The interrogator sends an Identify command (IdentifyCmnd) causing each device of a potentially large number of responding devices to select a random number from a known range and use it as that device's arbitration number. The interrogator sends an arbitration value (AVALUE) and an arbitration mask (AMASK) to a set of devices 12. The receivins devices 12 evaluate the following equation: (AMASK & AVALUE)═(AMASK & RV) wherein “&” is a bitwise AND function, and wherein “═” is an equality function. If the equation evaluates to “1” (TRUE), then the device 12 will reply. If the equation evaluates to “0” (FALSE), then the device 12 will not reply. By performing this in a structured manner, with the number of bits in the arbitration mask being increased by one each time, eventually a device 12 will respond with no collisions. Thus, a binary search tree methodology is employed.
An example using actual numbers will now be provided using only four bits, for simplicity, reference being made to FIG. 4. In one embodiment, sixteen bits are used for AVALUE and AMASK. Other numbers of bits can also be employed depending, for example, on the number of devices 12 expected to be encountered in a particular application, on desired cost points, etc.
Assume, for this example, that there are two devices 12 in the field, one with a random value (RV) of 1100 (binary), and another with a random value (RV) of 1010 (binary). The interrogator is trying to establish communications without collisions being caused by the two devices 12 attempting to communicate at the same time.
The interrogator sets AVALUE to 0000 (or “don't care” for all bits, as indicated by the character “X” in
Next, the interrogator sets AMASK to 0001 and AVALUE to 0000 and transmits an identify command. Both devices 12 in the field have a zero for their least significant bit, and (AMASK & AVALUE)═(AMASK & RV) will be true for both devices 12. For the device 12 with a random value of 1100, the left side of the equation is evaluated as follows (0001 & 0000)=0000. The right side is evaluated as (0001 & 1100)=0000. The left side equals the right side, so the equation is true for the device 12 with the random value of 1100. For the device 12 with a random value of 1010, the left side of the equation is evaluated as (0001 & 0000)=0000. The right side is evaluated as (0001 & 1010)=0000. The left side equals the right side, so the equation is true for the device 12 with the random value of 1010. Because the equation is true for both devices 12 in the field, both devices 12 in the field respond, and there is another collision.
Recursively, the interrogator next sets AMASK to 0011 with AVALUE still at 0000 and transmits an Identify command. (AMASK & AVALUE)═(AMASK & RV) is evaluated for both devices 12. For the device 12 with a random value of 1100, the left side of the equation is evaluated as follows (0011 & 0000)=0000. The right side is evaluated as (0011 & 1100)=0000. The left side equals the right side, so the equation is true for the device 12 with the random value of 1100. so this device 12 responds For the device 12 with a random value of 1010, the left side of the equation is evaluated as (0011 & 0000)=0000. The right side is evaluated, as (0011 & 1010)=0010. The left side does not equal the right side, so the equation is false for the device 12 with the random value of 1010. and this device 12 does not respond. Therefore, there is no collision, and the interrogator can determine the identity (e.g.. an identification number) for the device 12 that does respond.
De-recursion takes place, and the devices 12 to the right for the same AMASK level are accessed when AVALUE is set at 0010, and AMASK is set to 0011.
The device 12 with the random value of 1010 receives a command and evaluates the equation (AMASK & AVALUE)═(AMASK & RV). The left side of the equation is evaluated as (0011 & 0010)=0010. The right side of the equation is evaluated as (0011 & 1010)=0010. The right side equals the left side, so the equation is true for the device 12 with the random value of 1010. Because there are no other devices 12 in the subtree, a good reply is returned by the device 12 with the random value of 1010. There is no collision, and the interrogator can determine the identity (e.g., an identification number) for the device 12 that does respond.
By recursion, what is meant is that a function makes a call to itself. In other words, the function calls itself within the body of the function. After the called function returns, de-recursion takes place and execution continues at the place just after the function call; i.e. at the beginning of the statement after the function call.
For instance, consider a function that has four statements (numbered 1,2,3,4) in it, and the second statement is a recursive, call. Assume that the fourth statement is a return statement. The first time through the loop (iteration 1) the function executes the statement 2 and (because it is a recursive call) calls itself causing iteration 2 to occur. When iteration 2 gets to statement 2, it calls itself making iteration 3. During execution in iteration 3 of statement 1, assume that the function does a return. The information that was saved on the stack from iteration 2 is loaded and the function resumes execution at statement 3 (in iteration 2), followed by the execution of statement 4 which is also a return statement. Since there are no more statements in the function, the function de-recurses to iteration 1. Iteration 1, had previously recursively called itself in statement 2. Therefore, it now executes statement 3 (in iteration 1). Following that it executes a return at statement 4. Recursion is known in the art.
Consider the following code which can be used to implement operation of the method shown in FIG. 4 and described above.
Arbitrate(AMASK, AVALUE)
{
collision=IdentifyCmnd(AMASK, AVALUE)
if (collision) then
{
/* recursive call for left side */
Arbitrate((AMASK<<1)+1, AVALUE)
/* recursive call for right side */
Arbitrate((AMASK<<1)+1, AVALUE+(AMASK+1))
}
/* endif */
} /* return */
The symbol “<<” represents a bitwise left shift. means shift left by one place. Thus. 0001<<1 would be 0010. Note, however, that AMASK is originally called with a value of zero, and 0000<<1 is still 0000. Therefore, for the first recursive fall, AMASK=(AMASKL<<1)+1. So for the first recursive call, the value of AMASK is 0000+0001=0001. For the second call, AMASK=(0001<<1)+1=0010+1=0011. For the third recursive call. AMASK=(0011<<1)+1=0110+1=0111.
The routine generates values for AMASK and AVALUE to be used by the interrogator in an identify command “IdentifyCmnd.” Note that the routine calls itself if there is a collision. De-recursion occurs when there is no collision. AVALUE and AMASK would have values such as the following assuming collisions take place all the way down to the bottom of the tree.
AVALUE
AMASK
0000
0000
0000
0001
0000
0011
0000
0111
0000
1111*
1000
1111*
0100
0111
0100
1111*
1100
1111*
This sequence of AMASK, AVALUE binary numbers assumes that there are collisions all the way down to the bottom of the tree, at which point the Identify command sent by the interrogator is finally successful so that no collision occurs. Rows in the table for which the interrogator is successful in receiving a reply without collision are marked with the symbol “*”. Note that if the Identify command was successful at, for example, the third line in the table then the interrogator would stop going down that branch of the tree and start down another, so the sequence would be as shown in the following table.
AVALUE
AMASK
0000
0000
0000
0001
0000
0011*
0010
0011
. . .
. . .
This method is referred to as a splitting method. It works by splitting groups of colliding devices 12 into subsets that are resolved in turn. The splitting method can also be viewed as a type of tree search. Each split moves the method one level deeper in the tree.
Either depth-first or breadth-first traversals of the tree can be employed. Depth first traversals are performed by using recursion, as is employed in the code listed above. Breadth-first traversals are accomplished by using a queue instead of recursion. The following is an example of code for performing a breadth-first traversal.
Arbitrate(AMASK, AVALUE)
{
enqueue(0,0)
while (queue != empty)
(AMASK,AVALUE) = dequeue( )
collision=IdentifyCmnd(AMASK, AVALUE)
if (collision) then
{
TEMP = AMASK+1
NEW_AMASK = (AMASK<<1)+1
enqueue(NEW_AMASK, AVALUE)
enqueue(NEW_AMASK, AVALUE+TEMP)
}
/* endif */
endwhile
}/* return */
The symbol “!=” means not equal to. AVALUE and AMASK would have values such as those indicated in the following table for such code.
AVALUE
AMASK
0000
0000
0000
0001
0001
0001
0000
0011
0010
0011
0001
0011
0011
0011
0000
0111
0100
0111
. . .
. . .
Rows in the table for which the interrogator is successful in receiving a reply without collision are marked with the symbol “*”.
Thus,
A first predetermined number of bits, e.g. sixteen or an integer multiple of eight or sixteen bits, are established to be used as unique identification numbers. Respective devices 12 are provided with unique identification numbers respectively having the first predetermined numbers of bits, in addition to their random values RV. For example, such unique identification numbers are stored in memory in the respective devices 12.
A second predetermined number of bits are established to be used for the random values RV. The devices 12 are caused to select random values, RV. This is done, for example, by the interrogator 26 sending an appropriate command. Respective devices choose random values independently of random values selected by the other devices 12. Random number generators are known in the art.
The interrogator transmits a command requesting devices 12 having random values RV within a specified group of random values to respond, using a methodology similar to that described in connection with
Each devices 12 that receives the command determines if its chosen random value falls within the specified group by evaluating the equation (AMASK & AVALUE)═(AMASK & RV) and, if so, sends a reply, to the interrogator. The reply includes the random value of the replying device 12 and the unique identification number of the device 12. The interrogator determines if a collision occurred between devices that sent a reply and, if so, creates a new, smaller, specified group, by moving down the tree, skipping a level.
In the illustrated embodiment, every other level is skipped. In alternative embodiments, more than one level is skipped each time.
The trade off that must be considered in determining how many (if any) levels to skip with each decent down the tree is as following. Skipping levels reduces the number of collisions, thus saving battery power in the devices 12. Skipping deeper (skipping more than one level) further reduces the number of collisions. The more levels that are skipped, the greater the reduction in collisions. However, skipping levels results in longer search times because the number of queries (Identify commands) increases. The more levels that are skipped, the longer the search times. The inventors have determined that skipping just one level has an almost negligible effect on search time, but drastically reduces the number of collisions. If more than one level is skipped, search time increases substantially.
The inventors have determined that skipping every other level drastically reduces the number of collisions and saves battery power with out significantly increasing the number of queries.
After receiving a reply without collision from a device 12, the interrogator 26 can send a command individually addressed to that device by using its now known random value or its now known unique identification number.
The above described code for depth-first traversal is modified to provide for level skipping by increasing the number of recursive calls as shown below. For example, the above described code for depth-first traversal is replaced with code such as the following to provide for depth-first traversal employing level skipping.
Arbitrate(AMASK, AVALUE)
{
collision=IdentifyCmnd(AMASK, AVALUE)
if (collision) then
{
TEMP = AMASK+ 1
NEW_AMASK = (AMASK<<2)+3
Arbitrate(NEW_AMASK, AVALUE)
Arbitrate(NEW_AMASK, AVALUE+TEMP)
Arbitrate(NEW_AMASK, AVALUE+2*TEMP)
Arbitrate(NEW_AMASK, AVALUE+3*TEMP)
}
/* endif */
}/* return */
AVALUE and AMASK would have values such as those indicated in the following table for such code.
AVALUE
AMASK
0000
0000
0000
0011
0000
1111*
0100
1111*
1000
1111*
1100
1111*
0001
0011
0001
1111*
0101
1111*
1001
1111*
1101
1111*
0010
0011
0010
1111*
0110
1111*
1010
1111*
1110
1111*
. . .
. . .
Rows in the table for which the interrogator is successful in receiving a reply without collision are marked with the symbol “*”.
Similarly, the code provided above for breadth-first traversal can be readily modified to employ level skipping. Instead of inserting two items into the queue each time through the loop, four items are inserted into the queue each time through the loop. For either breadth-first traversal or depth-first traversal. AMASK will be shifted by two bits instead of one, and AVALUE will take on twice as many different values as in the case where level skipping is not employed.
Another arbitration method that can be employed is referred to as the “Aloha” method. In the Aloha method, every time a device 12 is involved in a collision, it waits a random period of time before retransmitting. This method can be improved by dividing time into equally sized slots and forcing transmissions to be aligned with one of these slots. This is referred to as “slotted Aloha.” In operation, the interrogator asks all devices 12 in the field to transmit their identification numbers in the next time slot. If the response is garbled, the interrogator informs the devices 12 that a collision has occurred, and the slotted Aloha scheme is put into action. This means that each device 12 in the field responds within an arbitrary slot determined by a randomly selected value. In other words, in each successive time slot, the devices 12 decide to transmit their identification number with a certain probability.
The Aloha method is based on a system operated by the University of Hawaii. In 1971, the University of Hawaii began operation of a system named Aloha. A communication satellite was used to interconnect several university computers by use of a random access protocol. The system operates as follows. Users or devices transmit at any time they desire. After transmitting, a user listens for an acknowledgment from the receiver or interrogator. Transmissions from different users will sometimes overlap in time (collide), causing reception errors in the data in each of the contending messages. The errors are detected by the receiver, and the receiver sends a negative acknowledgment to the users. When a negative acknowledgment is received, the messages are retransmitted by the colliding users after a random delay. If the colliding users attempted to retransmit without the random delay, they would collide again. If the user does not receive either an acknowledgment or a negative acknowledgment within a certain amount of time, the user “times out” and retransmits the message.
There is a scheme known as slotted Aloha which improves the Aloha scheme by requiring a small amount of coordination among stations. In the slotted Aloha scheme, a sequence of coordination pulses is broadcast to all stations (devices). As is the case with the pure Aloha scheme, packet lengths are constant. Messages are required to be sent in a slot time between synchronization pulses, and can be started only at the beginning of a time slot. This reduces the rate of collisions because only messages transmitted in the same slot can interfere with one another. The retransmission mode of the pure Aloha scheme is modified for slotted Aloha such that if a negative acknowledgment occurs, the device retransmits after a random delay of an integer number of slot times.
Aloha methods are described in a commonly assigned patent application (attorney docket number MI40-089) Ser. No. 09/026,248, filed Feb. 19, 1998, now U.S. Pat. No. 6,275,476B1 naming Clifton W. Wood, Jr. as an inventor, titled “Method of Addressing Messages and Communications System,” filed concurrently herewith, and which is incorporated herein by reference.
In one alternative embodiment, an Aloha method is combined with level skipping, such as the level skipping shown and described in connection with FIG. 5. For example, in one embodiment, devices 12 sending a reply to the interrogator 26 do so within a randomly selected time slot of a number of slots.
In compliance with the statute, the invention has been described in language more or less specific as to structural and methodical features. It is to be understood, however, that the invention is not limited to the specific features shown and described, since the means herein disclosed comprise preferred forms of putting the invention into effect. The invention is, therefore, claimed in any of its forms or modifications within the proper scope of the appended claims appropriately interpreted in accordance with the doctrine of equivalents.
Wood, Jr., Clifton W., Hush, Don
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