Method of time-synchronized data transmission in induction type power supply system
First Claim
1. A method of time-synchronized data transmission in induction type power supply system to achieve transmission of data signals and power between a supplying-end module used to transmit power and a receiving-end module used to feed back data signals, the method comprising the steps of:
- (a) starting program initialization by a supplying-end microprocessor and setting timing length of trigger pulse, start bit, logic state, end bit and data transmission loop and other functions following transmission of power from a power source of the supplying-end module;
(b) setting detection signal output frequency by the supplying-end microprocessor with frequency converter program to stop output frequency to a power driver unit;
(c) starting a standby timer by the supplying-end microprocessor and entering into sleeping and power-saving state after shutting down the output, and waking up upon completion of timing;
(d) starting and transmitting the detection signal upon completion of standby timing to activate the receiving-end module close to the supplying-end coil and then starting a voltage comparator installed in the supplying-end microprocessor;
(e) starting to count detection time and detecting if there is a trigger signal on signal analysis circuit with the voltage comparator in the supplying-end microprocessor;
proceeding to step (h) if there is no trigger signal;
otherwise, proceeding to step (f);
(f) deciding that there is no receiving-end module close to the supplying-end module if no trigger signal is found in the detection period and preparing to enter into standby mode;
(g) detecting the signal from the coil voltage detection circuit in the supplying-end microprocessor and checking if the voltage falls within the set range;
proceeding to step (b) to reset the detection signal output frequency if the voltage does not fall within the set range;
otherwise, proceeding to step (c) and shutting off the output;
(h) transmitting a trigger signal from the timer to examine signal check flag and determine if a first trigger signal is delivered, proceeding to step (i) if not, otherwise proceeding to step (k);
(i) deciding that the receiving-end module gets close to the supplying-end coil according to the first trigger signal and extending the detection signal transmission time to continuously transmit power to the receiving-end module through the supplying-end coil and make it operate;
(j) marking the signal check flag as an issued trigger signal, starting the trigger signal timer to get ready for detecting the next trigger and proceeding to step (e);
(k) sending a trigger signal from the time of the supplying-end microprocessor and checking if the start bit length is confirmed;
proceeding to step (l) if the start bit length is not confirmed;
otherwise, proceeding to step (m);
(l) checking if the issue time of the current signal and time length of the first trigger signal conform with the range of the start bit length;
proceeding to step (m) if yes, and proceeding to step (n) if not;
(m) marking the start bit flag as confirmation completed, resetting and restarting the trigger signal timer to get ready for detecting the next trigger;
(n) deciding that no desired receiving-end module is getting close by the supplying-end module if the start bit signal length does not comply with the set value, getting ready for shutting down the output and proceeding to step (f).
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Accused Products
Abstract
The present invention provides a method of time-synchronized data transmission in induction type power supply system, comprising timers and programs installed in a supplying-end module and a receiving-end module to predict the time for generating the trigger signal at the receiving-end end and perform steps for detecting signals to avoid omission. Under the condition of high power transmission, power output on the supplying-end coil is pre-reduced prior to the time expected for receiving trigger data, making the main carrier wave amplitude decrease in a short time period. In every process of data transmission, timers are mutually calibrated and synchronized again to transmit power without detecting and receiving in the period when no data are expected to be transmitted, thus preventing interference of power load noise and enabling the induction type power supply system to transmit data code stably.
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Citations
9 Claims
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1. A method of time-synchronized data transmission in induction type power supply system to achieve transmission of data signals and power between a supplying-end module used to transmit power and a receiving-end module used to feed back data signals, the method comprising the steps of:
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(a) starting program initialization by a supplying-end microprocessor and setting timing length of trigger pulse, start bit, logic state, end bit and data transmission loop and other functions following transmission of power from a power source of the supplying-end module; (b) setting detection signal output frequency by the supplying-end microprocessor with frequency converter program to stop output frequency to a power driver unit; (c) starting a standby timer by the supplying-end microprocessor and entering into sleeping and power-saving state after shutting down the output, and waking up upon completion of timing; (d) starting and transmitting the detection signal upon completion of standby timing to activate the receiving-end module close to the supplying-end coil and then starting a voltage comparator installed in the supplying-end microprocessor; (e) starting to count detection time and detecting if there is a trigger signal on signal analysis circuit with the voltage comparator in the supplying-end microprocessor;
proceeding to step (h) if there is no trigger signal;
otherwise, proceeding to step (f);(f) deciding that there is no receiving-end module close to the supplying-end module if no trigger signal is found in the detection period and preparing to enter into standby mode; (g) detecting the signal from the coil voltage detection circuit in the supplying-end microprocessor and checking if the voltage falls within the set range;
proceeding to step (b) to reset the detection signal output frequency if the voltage does not fall within the set range;
otherwise, proceeding to step (c) and shutting off the output;(h) transmitting a trigger signal from the timer to examine signal check flag and determine if a first trigger signal is delivered, proceeding to step (i) if not, otherwise proceeding to step (k); (i) deciding that the receiving-end module gets close to the supplying-end coil according to the first trigger signal and extending the detection signal transmission time to continuously transmit power to the receiving-end module through the supplying-end coil and make it operate; (j) marking the signal check flag as an issued trigger signal, starting the trigger signal timer to get ready for detecting the next trigger and proceeding to step (e); (k) sending a trigger signal from the time of the supplying-end microprocessor and checking if the start bit length is confirmed;
proceeding to step (l) if the start bit length is not confirmed;
otherwise, proceeding to step (m);(l) checking if the issue time of the current signal and time length of the first trigger signal conform with the range of the start bit length;
proceeding to step (m) if yes, and proceeding to step (n) if not;(m) marking the start bit flag as confirmation completed, resetting and restarting the trigger signal timer to get ready for detecting the next trigger; (n) deciding that no desired receiving-end module is getting close by the supplying-end module if the start bit signal length does not comply with the set value, getting ready for shutting down the output and proceeding to step (f). - View Dependent Claims (2, 3, 4, 5)
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6. A method of time-synchronized data transmission in induction type power supply system to achieve transmission of data signals and power between a supplying-end module used to transmit power and a receiving-end module used to feed back data signals, the method comprising the steps of:
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(a1) initializing the data signal receiving program in the supplying-end module and setting the values of main timing loop and other items following transmission of power from the supplying-end module; (b1) starting and transmitting the main timing loop of data transmission and performing programmed operations at a scheduled time; (c1) performing initialization of the transmission power pre-reduction check and control program within 3mS before a timer of the main timing loop of transmission is cleared to zero; (d1) checking trigger signal that indicates a first trigger range of a start signal;
if a trigger signal is found within 2.5 mS±
0.5 mS prior to zero clearing of the timer for the main timing loop of transmission, proceeding to step (e1);
otherwise, proceeding to step (f1);(e1) marking signal check flag as a transmitted trigger signal, starting the trigger signal timer to prepare for the next trigger and proceeding to step (f1); (f1) performing initialization of a transmission power recovery check and control program within 2 mS prior to zero clearing of the timer for the main timing loop of transmission; (g1) performing initialization of the transmission power pre-reduction check and control program within 0.5 mS prior to zero clearing of the timer for the main timing loop of transmission; (h1) checking the trigger signal that indicates a second trigger range of the start signal;
if a bit length is found to be in inconformity with the set range within ±
0.5 mS prior to zero clearing of the timer for the main timing loop of transmission, proceeding to step (i1);
if both triggers are completed and the length range is satisfied, proceeding to step (m1);(i1) recording a failed transmission if the supplying-end microprocessor does not correctly receive two triggers whose bit lengths comply with the set range, shutting off a voltage comparator used for detecting the trigger signal, executing the transmission power recovery check and control program, and resetting the timing when the main timing loop returns to zero; (j1) deciding if a number of failed transmission is greater than a set upper limit value;
proceeding to step (k1) if the upper limit value is reached;
otherwise, proceeding to step (b1);(k1) if no trigger signal is received within a expected time period, deciding that data transmission is failed, getting ready to terminate output from the supplying-end coil and entering into a standby mode; (m1) if two triggers of the start bit fall within the set range, deciding that the start bit signal is fed from the receiving-end module correctly, clearing the timer for the main timing loop again and restarting the timer to synchronize the timer in the supplying-end microprocessor with the timer for the main loop of data transmission in the receiving-end microprocessor; (n1) starting to receive data bits, and after the timer for receiving data bits is cleared to zero, restarting the supplying-end microprocessor; (o1) checking signal flag that indicates completion of receiving to decide if a check is needed;
proceeding to step (o11) if check is needed;
otherwise, proceeding to step (p1);(o11) performing initialization of the transmission power pre-reduction check and control program when timer for detection of data bit receiving runs for 2.25 mS in the supplying-end microprocessor; (o12) checking the trigger signal and deciding that the data length of the end bit signal received is 2.5 mS±
0.5 mS;(o13) executing the transmission power recovery check and control program when the timer for detection of data bit receiving runs for 2.75 mS in the supplying-end microprocessor; (o14) transmission being completed, transferring the data into the supplying-end microprocessor for internal use and preparing to receive data in the next data transmission loop, and then proceeding to step (b1); (o15) deciding that data transmission is failed if no triggering happened within the expected time period, executing the transmission power recovery check and control program, and proceeding to step (ji); (p1) performing initialization of the transmission power pre-reduction check and control program when the timer for detection of data bit receiving runs for 1.75 mS in the supplying-end microprocessor; (q1) checking the trigger signal;
if the triggering happened within 2 mS±
0.5 mS, deciding that the data length of logic 0 signal received is 2 mS and proceeding to step (qi1);
if no triggering happened, proceeding to step (r1);(q11) clearing the timer for detection of data bit receiving to zero at the triggering point and restarting it, then marking the received data signal as logic 0; (q12) executing the transmission power recovery check and control program when the timer for detection of data bit receiving runs for 0.25 mS in the supplying-end microprocessor; (q13) storing the received logic bits into (Rx) data buffer cyclically in sequence from the most significant bit to the least significant bit, and adding one count to data counter; (q14) checking if a number of data transmission has been equal to that of transmitted data bits;
if yes, proceeding to step (q15);
otherwise, proceeding to step (q16);(q15) having received incomplete data bit, and preparing to receive the trigger next time, and proceeding to step (c1); (q16) the supplying-end microprocessor having received a complete data bit, marking an end bit flag that needs to be checked, preparing to receive the next trigger and proceeding to step (c1); (r1) executing the transmission power recovery check and control program when the timer for detection of data bit receiving runs for 2.25 mS in the supplying-end microprocessor; (s1) executing the transmission power recovery check and control program when the timer for detection of data bit receiving runs for 2.75 mS in the supplying-end microprocessor; (t1) checking the trigger signal, deciding that the data length of the logic 1 bit signal received is 3 mS±
0.5 mS, and proceeding to step (u1);
proceeding to step (o15) if the triggering does not happen;(u1) clearing the timer for detection of data bit receiving to zero and restarting the supplying-end microprocessor, and then marking the received data as logic 1; (v1) executing the transmission power recovery check and control program when the timer for detection of data bit receiving runs for 0.25 mS in the supplying-end microprocessor and proceed to step (q12) continuously. - View Dependent Claims (7, 8, 9)
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Specification