Patent Application
20070181078
1. Field of the Invention
The present invention relates to remote dog training systems, and, more particularly, to signal processing relative to the dog training system's transmitters/receivers.
2. Description of the Related Art
Remote dog training systems typically provide at least one stimulus, via a transmitter operated by a human trainer, to a dog which is typically wearing a collar with a receiver which is responsive to the trainer's transmitter. The stimuli can include a sound/tone activation and/or an electrical stimulation, although other stimulation such as a vibrational stimulus can be used. The electrical stimulation is provided to the dog through receiver electrodes which are in contact with some part of the dog's neck. In order to accommodate differences between breeds, individual dog temperament, training conditions, etc., it is advantageous to provide a wide range of possible stimulation, which range is selectable at the transmitter by the trainer. For example, the general difference in coat/skin of one breed versus another breed may provide a general difference in contact resistance, which can generally make a given breed more correctable at a lower electrical stimulation than another breed which has a thicker coat with a downy underlayer, for example. Further, a relatively strong willed dog may require more stimulation for a given training condition than a more amenable dog. Yet further, training conditions can play a large role in determining the amount of stimulation necessary for a given dog. For example, if a dog is being trained to hunt upland gamebirds, and the hunter and/or dog inadvertently spooks a deer which is bedding nearby, the dog can easily become almost completely focused on coursing the deer. In such conditions, the hunter may need to provide a much higher level of stimulation to the dog to correct the dog from chasing the deer, and to resume the bird hunt.
Depending on terrain and/or cover conditions, the hunter may not be aware of the fact that the dog is chasing a deer, and therefore needs immediate strong correction, until the dog is a considerable distance from the hunter/trainer. As the distance between the dog and trainer increases, the need for correction may correspondingly increase, as the deer may cross a hazard such as a road with the following dog unaware or unconcerned about possible oncoming traffic. Although the above example is relative to a sporting dog, a similar situation arises in the case of off-leash obedience training of a companion dog in the presence of a darting squirrel, for example. The effective range of a transmitter/receiver pair, that is the maximum distance between a remote dog training transmitter and receiver for which a correction command transmitted by the transmitter, and is reliably received and executed by the receiver, is a function of many factors such as transmitted power output, receiver sensitivity, antenna efficiency, noise, interference, atmospheric conditions and other elements. In the case of at least some of the physical parameters of a dog training system, such as transmitted power output, receiver sensitivity and antenna efficiency, increasing the performance of these elements to increase the effective range of the system adds cost to the system components. A possible alternative to adding cost by improving component performance is increasing system performance through appropriate signal processing.
A control system and method for remote launchers (of gamebirds or training dummies) for dog training discloses a transmission signaling which includes the transmission of sixteen timing pulses, followed by a packet of information including three consecutive identification (ID) bytes constituting the address or identification of the particular launcher unit to which the transmission is intended, followed by a one-byte function code, and that is followed by a checksum byte. The checksum byte is followed by a 1400 microsecond delay before the packet of three ID bytes are re-sent. A parity bit at the end of that sequence is checked. Although the checksum byte and parity bit can possibly detect errors in the transmission, there is no accommodation for correcting any detected error. Further, although the packet of three ID bytes are re-sent, which gives a second chance to correctly identify the launcher unit to be activated, the function code is not re-sent; therefore an error in the function code causes an error in the launcher thereby reducing the system reliability.
What is needed in the art is a method and apparatus for increasing the effective range and reliability of a dog training system without increasing the cost of the system components.
The present invention provides a signal and protocol for a remote dog training system which includes forward error correction and a repeat transmission.
The invention comprises, in one form thereof, a transmitter for a dog training system, the transmitter having a command input device for inputting a training command input into the transmitter, and a transmitter controller connected to the command input device. The transmitter controller translates the training command input into identification data and command data. The transmitter controller also generates at least one forward error correction codeword from the identification data and the command data.
The invention comprises, in another form thereof, a dog training system, having a receiver, and a transmitter in electromagnetic communication with the receiver. The transmitter has a command input device which inputs a training command input into the transmitter, and a transmitter controller connected to the command input device. The transmitter controller translates the training command input into identification data and command data. The transmitter controller also generates at least one forward error correction codeword from the identification data and the command data.
The invention comprises, in yet another form thereof, a method of electromagnetic signaling between a transmitter and a receiver in a dog training system, including the steps of: receiving a training command input from a command input device of the transmitter; communicating the training command input to a transmitter controller connected to the command input device; translating the training command input by the transmitter controller into identification data and command data; and generating by the transmitter controller at least one forward error correction codeword from the identification data and the command data.
An advantage of the present invention is that it increases the effective range and reliability of a dog training system without increasing the cost of the system components
Another advantage of the present invention is that it improves the performance (including at least the effective range and reliability) of a dog training system without increasing the cost of the system components.
Yet another advantage of the present invention is that it accommodates a larger number of stimulation pulses, and therefore, a wide low to high stimulation range.
The above-mentioned and other features and advantages of this invention, and the manner of attaining them, will become more apparent and the invention will be better understood by reference to the following description of embodiments of the invention taken in conjunction with the accompanying drawings, wherein:
Corresponding reference characters indicate corresponding parts throughout the several views. The exemplifications set out herein illustrate one preferred embodiment of the invention, in one form, and such exemplifications are not to be construed as limiting the scope of the invention in any manner.
Referring now to the drawings, and more particularly to
Transmitter 12 generally can be a handheld device which includes a housing, and which has a command input device 16 for inputting a training command input into transmitter 12. Transmitter 12 can also include a display, such as an LCD display, which provides a visual feedback and verification of transmitter 12 functions which are selected by the trainer. Command input device 16 can be a pushbutton, multiple pushbuttons, a combination of set switches and pushbutton(s), a touchpad, a rotary selector switch, some combination thereof, or other input elements. Transmitter 12 can be used with multiple receivers 14, or multiple dogs, and a trainer selects the dog(s) to be corrected, the stimulation to be provided, and the level of stimulation by touching appropriate input elements on command input device 16. For example, command input device 16 can include 8 pushbuttons or touchpads with the following functionality: BOOST, TONE PROXIMITY, COLLAR SELECT, UP ARROW, PRIMARY STIMULATION, DOWN ARROW, CONTINUOUS/MOMENTARY, and PROGRAM, although the present invention is not limited by, or to, such functionality. Command input device 16 communicates the training command input to transmitter controller 20 using a plurality of electrical connections 18 between command input device 16 and transmitter controller 20.
Transmitter controller 20 translates the training command input into identification data 22 and command data 24. In the embodiment shown in
A pattern of 1/0 transitions proceeding the codewords is needed for clock synchronization and DC stabilization. The period is be referred to hereafter as the PREAMBLE (
a) codeword 1=15 bit BCH codeword
b) Determine the number of 1's which are present in codeword 1.
c) If the number of 1's=>9, then 4 bit pattern=0000.
d) If the number of 1's=8, then 4 bit pattern=0001.
e) If the number of 1's=7, then 4 bit pattern=1110.
f) If the number of 1's<=6, hen 4 bit pattern=1111.
Transmitter controller 20 generates a first transmission packet 32 with forward error correction codewords 26, 28, 30. First transmission packet 32 includes a 14 bit digital preamble 42 (PREAMBLE), a sync byte 44 (SYNC), codeword 1 (26), 4 bits of one-zero leveling, codeword 2 (28), 4 bits of one-zero leveling and codeword 3 (30). A modulator 34 is connected to transmitter controller 20. A transmitter antenna 36 is connected to modulator 34, and transmitter 12 produces a wireless signal 38 of first transmission packet 32. Modulator 34 can be a frequency-shift keying (FSK) modulator, for example, where the digital 1s and 0s of first transmission packet 32 are represented by two frequencies, where one frequency is used to represent a binary zero, and another frequency is used to represent a binary one, and where the output frequency has no phase discontinuity. A sample first transmission packet 32 is given in Table 5.
Wireless signal 38 includes a second transmission packet 40 following first transmission packet 32, where second transmission packet 40 is substantially identical to first transmission packet 32.
Receiver 14 is typically connected to a collar which is worn by the dog, and includes a receiver antenna 46 connected to a demodulator 48 which is connected to a receiver controller 50. Receiver 14 receives wireless signal 38 by receiver antenna 46. Demodulator 48 demodulates wireless signal 38 to produce a received first transmission packet 52. Demodulator 48 can be an FSK demodulator which reconverts the signal into a voltage and/or current binary signal. Receiver controller 50 decodes and error corrects received first transmission packet 52. Tables 6-9 illustrate how the codewords of first transmission 52 are decoded and error corrected.
The bch1 507[ ] table is provided in Table 9. It resides in FLASH memory as a CONST.
Wireless signal 38 includes second transmission packet 40 following first transmission packet 32. If received first transmission packet 52 includes non-correctable errors (8 FEC bits can detect and correct for any 2 bit error in the 15 bit word so that a non-correctable error is one having three or more error bits), demodulator 48 demodulates wireless signal 38 to produce a received second transmission 54 packet. Receiver controller 50 decodes and error corrects the codewords of received second transmission 54 as illustrated in Tables 6-9. The present invention provides a signal-plus-noise-plus-distortion to noise-plus-distortion ratio (SINAD) gain due to the forward error correction as follows.
g) desired packet (or signal) success rate=(bit success rate)length of packet
h) packet success rate=0.99
i) bit success rate=(1−bit error rate)
For the signal and protocol described previously, the packet length is 45 bits (three 15 bit codewords).
j) 0.99=(1−BER)45
k) 0.9997767=(1−BER)
l) BER (bit error rate)=2.233×10−4
Thus, for an unprotected packet length of 45 bits, a BER of 0.000233 is required for a success rate of 0.99. As mentioned previously, BCH(15,7) will tolerate 2 errors in the 15 bit codeword. This equates to a BER tolerance of 0.1333. Standard curves for SINAD versus error probability for FSK data transmissions are available in “Digital and Analog Communication Systems”, K. SamShanmugam as well as other sources. The SINAD required for a 10−4 BER is roughly 15 dB and the SINAD required for a 10−1 BER is roughly 9 dB, thus providing a coding gain of roughly 6 db for a 45 bit transmission. At a given success rate, error correction coding can operate at a lower SINAD which translates into increased range at the same success rate.
To compare the present invention to a transmission signal composed of 16 unprotected data bits, the BER required for a 0.99 transmission success rate is as follows.
m) 0.99=(1−BER)16
n) 0.9997767=(1−BER)
o) BER=6.28×10−4
Again, this roughly equates to a SINAD of 15 dB for FSK. With the forward error correction coding gain of 6 dB of the present invention, a range improvement can be expected which is given by:
p) 6=20 log(d); considering only free space loss OR
q) 6=33.2 log(d); considering a more practical loss profile of 10 dB per doubling of the distance. Therefore,
r) d=1.5; or a 50% increase in range for the same performance level.
Further, the present invention has the additional advantage of, if received first transmission packet 52 has more than 2 bits of errors (uncorrectable error), receiver 14 listens to wireless signal 38 to produce a received second transmission packet 54, which gives receiver 14 a second chance to execute the trainer's command.
Receiver controller 50 uses the decoded and error corrected transmission packet to activate tone switch 62 and/or stimulation switch 56, which are both connected to receiver controller 50, according to the trainer's command inputted at command input device 16 by the trainer. If tone switch 62 is activated, switch 62 correspondingly activates annunciator 64 to provide correction to the dog with a tone or other sound. If stimulation switch 56 is activated, switch 56 correspondingly activates transformer 58, which using the transformer flyback principal of operation for example, provides correction to the dog with electrical stimulation through electrodes 60. Although the present invention obviously includes the remote functions of tone activation and stimulation activation, provisions are included to allow for expanding the set of remote functions (i.e., beeper functions (a beeper is worn on the dog collar and produces a sound that is detectable by the trainer to locate the dog in heavy cover, among other functions), and auxiliary devices such as launchers).
The transmission protocol of the present invention can be used with “high end” training products, with a relatively large degree of functionality, and with which it is desirable to have a wide (low to high) stimulation range. Each of the transmission packets is 75 ms long (75 bits/1000 bps) and there are 8 ms gaps between the transmissions. The correction period outputted by receiver controller 50 starts at the end of a successfully decoded transmission, when receiver 14 has disabled signal reception, and starts with a 6 ms period (decode+hardware reconfigure time+stimulation capacitor charge time), followed by up to 15 fundamental correction widths of 5.3 ms, and ending with 5 ms hardware reconfigure+settling time. Therefore, the correction pulse period=(15×5.3 ms)+0.3 ms=79.8 ms (allows for a maximum of 16 stimulation pulses), and the deaf period=correction period+startup+settling=79.8 ms+6 ms+5 ms=90.8 ms. Each fundamental correction or stimulation period of 5.3 ms includes time period TW1=300 μs (microsecond), followed by time period TW2=500 μs, followed by time period TW3=4000 μs, followed by time period TW4=500 μs. TW1 time is used to generated the stimulation pulse width which can range from a minmum of 1.2 μs to a maximum of 300 μs. At the conclusion of TW1 the stimulation output capacitor begins to recharge. There is 5000 μs available for this capacitor to recharge. TW2 is used as buffer between stimulation and start of tone. Ta occurs at 800 μs from the start of each fundamental correction width. It is the time at which the tone may begin. TW3 is filled with as many cycles of the desired tone as possible. Th occurs at 4800 μs from the start of each fundamental correction width. It is the time at which the tone must end. TW4 is used as buffer between tone and the start of the next correction width. After TW1 in correction width 16, the stimulation enable signal is made FALSE and the reconfiguration and settling of the receiver hardware may begin.
In use the present invention discloses a method (
The method of the present invention can be implemented in hardware, software, firmware, or some combination thereof.
While this invention has been described as having a preferred design, the present invention can be further modified within the spirit and scope of this disclosure. This application is therefore intended to cover any variations, uses, or adaptations of the invention using its general principles. Further, this application is intended to cover such departures from the present disclosure as come within known or customary practice in the art to which this invention pertains and which fall within the limits of the appended claims.
