Title of Invention	VALVE CONTROL SYSTEM
Abstract	Apparatus and methods are provided for diagnosing faults in multiple, associated motor-resolver systems. One apparatus includes a swapping circuit coupling a first resolver to a first or second decoder, and a swapping circuit coupling a second resolver to the first or second decoder. One method includes applying a signal from a resolver to a first decoder to determine that the first decoder is lfunctioning if the first decoder continues to generate a fault signal, and applying a signal from a different resolver to a second decoder to determine that a motor associated with the first decoder is malfunctioning if the second decoder generates a fault signal. Another method includes transmitting a signal from a resolver to first and second decoders, transmitting a signal from a different resolver to the first and second decoders, and determining if the first decoder, second decoder, a first motor, or a second motor is malfunctioning.

Title of Invention

VALVE CONTROL SYSTEM

Abstract

Apparatus and methods are provided for diagnosing faults in multiple, associated motor-resolver systems. One apparatus includes a swapping circuit coupling a first resolver to a first or second decoder, and a swapping circuit coupling a second resolver to the first or second decoder. One method includes applying a signal from a resolver to a first decoder to determine that the first decoder is lfunctioning if the first decoder continues to generate a fault signal, and applying a signal from a different resolver to a second decoder to determine that a motor associated with the first decoder is malfunctioning if the second decoder generates a fault signal. Another method includes transmitting a signal from a resolver to first and second decoders, transmitting a signal from a different resolver to the first and second decoders, and determining if the first decoder, second decoder, a first motor, or a second motor is malfunctioning.

Full Text	1 APPARATUS AND METHODS FOR DIAGNOSING MOTOR-RESOLVER SYSTEM FAULTS FIELD OF THE INVENTION [00011 The present invention generally relates to motor-resolver systems, and more particularly relates to apparatus and methods for diagnosing faults in multiple, associated motor-resolver systems. BACKGROUND OF THE INVENTION [0002] Motor-resolver systems are typically employed to accurately sense and control the position of rotating shafts. As a motor is employed to a resolvcr at a particular rate or rotational velocity, the output of the resolver is then fed to a motor controller to determine if the motor is properly driving the shafts. When a resolver anomaly is detected, the motor controller notifies the user with an error message (e.g., a visual warning, an audio warning, etc.). [0003] Some devices (e.g., a hybrid vehicle) include multiple motors (and multiple resolvers) coupled to a single motor controller. In these devices, the motor controller often includes a resolver decoder for each respective resolver. For example, a hybrid vehicle includes a first motor for operation with the electric portion of the vehicle, and a second motor for operation with the combustion portion of the vehicle. The resolver associated with the first motor is coupled to a first resolver decoder, and the resolver associated with the second motor is coupled to a second resolver decoder within the common motor controller. [0004] There are times, however, when one of the resolvers is malfunctioning and the motor controller transmits a warning to the user indicating that the motor coupled to the malfunctioning resolver is not working properly when in fact, it is the resolver decoder that is not working properly. Thus, it is often difficult to determine which of the resolver or the 2 resolver decoder is malfunctioning when the motor controller transmits an error message. [0005] Since replacing a motor (and resolver) or a motor controller are expensive, it is desirable to provide efficient systems and methods for testing a motor (via its resolver) and a resolver decoder coupled to the resolver to determine which of the motor/resolver and the motor controller is malfunctioning when the motor controller transmits an error message without replacing the motor or motor controller of a vehicle system (e.g., a hybrid vehicle system). Furthermore, other desirable features and characteristics of the present invention will become apparent from the subsequent detailed description of the invention and the appended claims, taken in conjunction with the accompanying drawings and this background of the invention. BRIEF SUMMARY OF THE INVENTION [0006] Various exemplary embodiments of the invention provide apparatus and methods for diagnosing faults in multiple, associated motor-resolver systems. For multiple, associated motor-resolver systems including a first resolver, a second resolver, and a motor controller including a first decoder and a second decoder, one system includes a first swapping circuit selectively coupling the first resolver to the first decoder or the second decoder, and a second swapping circuit selectively coupling the second resolver to the first decoder or the second decoder. [0007] For multiple, associated motor-resolver systems including (i) a first motor resolver that transmits a first resolver signal to a first decoder and (ii) a second motor resolver that transmits a second resolver signal to a second decoder, wherein the first and second decoders are each configured to detect fault conditions represented in the first and second resolver signals, respectively, and configured to generate a first and second fault signal, respectively, in response to detecting a fault condition, and wherein the first 3 fault signal has been generated, one method for diagnosing faults includes the step of applying the second signal to the first decoder to determine that the first decoder is malfunctioning if the first decoder continues to generate the first fault signal. This method also includes the step of applying the first signal to the second decoder to determine that the first motor is malfunctioning if the second decoder generates the second fault signal. [0008] One method for diagnosing faults in multiple, associated motor- resolver systems including a first motor having an associated first resolver, a second motor having a second associated resolver, and a motor controller having a first decoder and a second decoder includes the steps of transmitting a first signal from the first resolver to the first decoder and transmitting a second signal from the second resolver to the second decoder. This method also includes the steps of transmitting a third signal from the first resolver to the second decoder and transmitting a fourth signal from the second resolver to the first decoder. After the first, second, third, and fourth signals are transmitted, which of the first decoder, the second decoder, the first motor, or the second motor is malfunctioning can be determined. BRIEF DESCRIPTION OF THE DRAWINGS [0009] The present invention will hereinafter be described in conjunction with the following drawing figures, wherein like numerals denote like elements, and [0010] FIG. 1 is a schematic diagram of a prior art system having multiple, associated motor-resolver systems; [0011] FIG. 2 is a schematic diagram of an exemplary embodiment of a device for diagnosing faults in the system of FIG. 1; [0012] FIG. 3 is a schematic diagram of one exemplary embodiment of a resolver simulator included in the device of FIG. 2; 4 [0013] FIG. 4 is a flow diagram representing one exemplary embodiment of a method for diagnosing faults in the system of FIG. 1; [0014] FIG. 5 is a flow diagram representing another exemplary embodiment of a method for diagnosing faults in the system of FIG. 1; and [0015] FIG. 6 is a flow diagram representing yet another exemplary embodiment of a method for diagnosing faults in the system of FIG. 1. DETAILED DESCRIPTION OF THE INVENTION [0016] The following detailed description of the invention is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. Furthermore, there is no intention to be bound by any theory presented in the preceding background of the invention or the following detailed description of the invention. [0017] FIG. 1 is a schematic of a prior art system 10 including a motor- resolver system 100 and a motor-resolver system 150. Motor-resolver system 100 includes a resolver 105 coupled to a motor 110. Resolver 105 is configured to transmit signals representing the operating characteristics (e.g., motor speed, rotor angle, signal strength, connectivity, etc.) of motor 110 to a motor controller 120. [0018] Similarly, motor-resolver system 150 includes a resolver 155 coupled to a motor 160. Resolver 155 is also configured to transmit signals representing the operating characteristics of motor 160 to motor controller 120. [0019] Motor controller 120 includes a resolver decoder 1250 for receiving signals from resolver 105 and a resolver decoder 1275 for receiving signals from resolver 155. Resolver decoders 1250 and 1275 are each configured to monitor the operating characteristics of their respective motors (via resolvers 150 and 155) and transmit an error message when motor 110 or 160 are malfunctioning, respectively. 5 [0020] When malfunctioning, motor 110 and 160 may exhibit at least one of multiple possible fault conditions. One fault condition occurs when motors 110 and 160 are rotating too fast. This fault condition is referred to as a "loss of tracking" condition. A loss of tracking condition is detected by resolver decoders 1250 and 1275 when the frequency of the signals transmitted from resolver 105 and/or 155 is greater than a pre-determined threshold frequency of the signals or the resolver signal shows an exceedingly large rotational acceleration. [0021] A "degraded signal" is another fault condition that may occur in motors 110 and 160. A degraded signal condition is detected by resolver decoders 1250 and 1275 when the peak-to-peak voltage amplitude of the signals transmitted from resolvers 105 and 155 are greater than a pre- determined threshold voltage. Since each resolver typically includes two sine wave feedback outputs and two cosine feedback outputs, the degraded signal may be found from either the sine or cosine feedback signals. Additionally, if the difference between the peak-to-peak voltage amplitudes of the sine and cosine signals is greater than a pre-determined value, the degraded signal fault may be logged by the corresponding resolver decoder. [0022] Another fault condition that may be experienced by motors 110 and 160 is a "loss of signal" condition. A loss of signal fault condition is detected by resolver decoders 1250 and 1275 when the peak-to-peak voltage amplitude of the signals transmitted from resolvers 105 and/or 155 are less than a pre- determined threshold. Since each resolver typically includes sine wave feedback outputs and cosine feedback outputs, the loss of signal fault conditions for each resolver may be caused by the loss of signal strength in any of the feedback outputs, the extreme case being an open circuit in one or more resolver wire connections. 6 [0023] A "DC bias Out-Of-Range (OOR)" condition is another fault condition that may be experienced by resolvers 105 and 155. A DC bias OOR fault condition is detected when the DC bias of the signals output by the pair of sine wave feedback outputs and/or the pair of cosine wave feedback outputs is either too high or too low. A short circuit condition to the power supply or circuit ground is a typical DC bias OOR fault condition that may be experienced by resolvers 105 and 155. [0024] FIG. 2 is a schematic diagram of an exemplary embodiment of a device 200 for diagnosing faults in system 10. Device 200 may be inserted in, for example, a wire harness (not shown) between resolvers 105/155 and motor controller 120. Device 200 includes a connector 202, a connector 204, a connector 206, and a connector 208 to detachably couple device 200 to system 10. That is, connector 202 is configured to couple resolver 105 to device 200, connector 204 is configured to couple resolver 155 to device 200, connector 206 is configured to couple resolver decoder 1250 to device 200, and connector 208 is configured to couple resolver decoder 1275 to device 200. [0025] Device 200 also includes a swapping circuit 210 coupled to a swapping circuit 220. Swapping circuit 210 is configured to selectively switch between being coupled to a resolver simulator 300 {see FIG. 3) and connector 202. Swapping circuit 220 is configured to selectively switch between being coupled to connector 206 and connector 208. Accordingly, resolver simulator 300 or connector 202 may be coupled to either connector 206 or connector 208. Similarly, connector 206 or connector 208 may be coupled to either resolver simulator 300 or connector 202. [0026] Device 200 also includes a swapping circuit 230 coupled to a swapping circuit 240. Swapping circuit 230 is configured to selectively switch between being coupled to resolver simulator 300 or connector 204. Swapping circuit 240 is configured to selectively switch between being coupled to connector 206 or connector 208. Accordingly, resolver simulator 300 or 7 connector 204 may be coupled to either connector 206 or connector 208. Similarly, connector 206 or connector 208 may be coupled to either resolver simulator 300 or connector 204. [0027] A controller 250 coupled to swapping circuits 210, 220, 230, and 240 is also included in device 200. Controller 250 is also coupled to a connector 255 configured to detachably couple device 200 to motor controller 120. [0028] Controller 250 is configured to operate in a plurality of modes (e.g., a run/crank mode, an accessory mode, etc.) to test (discussed below) motor 110 (via resolver 105), motor 160 (via resolver 155), resolver decoder 1250, and/or resolver decoder 1275. The accessory mode enables device 200 to "swap" between the various components of device 200. That is, controller 250 is configured to transmit a signal to swapping circuit 210, 220, 230, and/or 240 instructing one or more of these swapping circuits to switch from being coupled to one component, to being coupled to another component. For example, controller 250 may transmit a signal to swapping circuit 210 (when the vehicle key is in the accessory position, but not in the run/crank position) instructing swapping circuit 220 to switch from being coupled to connector 206 (i.e., resolver decoder 1250) to being coupled to connector 208 (i.e., resolver decoder 1275). Controller 250 may, at substantially the same time, instruct swapping circuit 230 to switch from being coupled to connector 204 (i.e., resolver 155) to being coupled to resolver simulator 300. As one skilled in the art will appreciate, controller 250 is able to transmit signals to swapping circuit 210, 220, 230, and/or 240 to enable any combination of resolver simulator 300, resolver 105, or resolver 155 to be coupled to resolver decoder 1250 or resolver decoder 1275 when operating in accessory mode. 8 [0029] In addition, controller 250 is configured to couple resolver simulator 300 to resolver decoder 1250 (via swapping circuits 210 and 220) and resolver decoder 1275 (via swapping circuits 230 and 240) at the same time. Here, resolver simulator 300 is capable of simulating both resolver 105 and resolver 155 to test resolver decoders 1250 and 1275 at the same time. That is, controller 250 may couple resolver 105 and resolver 155 to a respective one of resolver decoders 1250 and 1275, and then switch the coupling (via swapping circuits 220 and 240) of resolver 105 and resolver 155 to the other one of resolver decoders 1250 and 1275. [0030] FIG. 3 is a schematic diagram of one exemplary embodiment of resolver simulator 300 {see FIG. 2). Resolver simulator 300 includes an adjustable waveform generator 310 configured to generate waveforms (e.g., square waves) representing an output of a motor (e.g., motor 110 or 160). Moreover, the frequency of the signals generated by waveform generator 310 may be adjusted to simulate a "loss of tracking" fault condition of a motor (i.e., the motor is rotating too fast) or normal speeds of a motor. The output of waveform generator 310 is coupled to a sine wave circuit 320 and to a cosine wave circuit 330. [0031] Sine wave circuit 320 is configured to simulate a pair of sine wave feedback outputs of resolvers 105 and 155. To accomplish this, sine wave circuit 320 includes a low pass filter 3205 having an output coupled to a gain adjustment circuit 3310. Low pass filter 3205 and gain adjustment circuit 3310 operate to transform the square waves generated by waveform generator 310 into sine waves. [0032] Also included in sine wave circuit 320 is a switch 3215 (e.g., a single pole, double throw (SPDT) switch) to selectively couple gain adjustment circuit 3210 or a reference voltage 340 (discussed below) to a buffer 3320. Sine wave circuit 320 also includes a signal multiplier circuit 3225 coupled to the output of buffer 3220. The output of signal multiplier circuit 3225 is 9 coupled to an adder 3230, and adder 3230 is coupled to an adjustable DC offset circuit 3235. DC offset circuit 3235 is configured to adjustably (either automatically and/or manually via, for example, a potentiometer 3237) increase or decrease the DC bias of the sine waves generated by sine wave circuit 320 to simulate a short circuit condition or a non-short circuit condition. [0033] The output of adder 3230 is coupled to a buffer 3248 and to a phase shift circuit 3254. Buffer 3248 is configured to the amplify signals received from adder 3230, and the output of buffer 3248 is coupled to an output 3240 of sine wave circuit 320. [0034] Phase shift circuit 3254 is configured to shift the phase of the signals received from adder 3230 by 180°, and the output of phase shift circuit 3254 is coupled to another output 3250 of sine wave circuit 320. [0035] Cosine wave circuit 330 is configured to simulate a pair of cosine wave feedback outputs of resolvers 105 and 155. Cosine wave circuit 330 includes an output of a low pass filter 3305 coupled to a phase shift circuit 3307. The output of phase shift circuit 3307 is coupled to a gain adjustment circuit 3310. Low pass filter 3305, phase shift circuit 3307, and gain adjustment circuit 3310 operate to transform the square waves generated by waveform generator 310 into sine waves (via low pass filter 3305) and then into cosine waves (via phase shift circuit 3307). [0036] Also included in cosine wave circuit 330 is a switch 3315 (e.g., a single pole, double throw (SPDT) switch) to selectively couple the output of gain adjustment circuit 3310 or a reference voltage 340 (discussed below) to a buffer 3320. [0037] Cosine wave circuit 330 also includes a signal multiplier circuit 3325 having an input coupled to buffer 3320. The output of signal multiplier circuit 3325 is coupled to an adder 3330, and adder 3330 is also coupled to an adjustable DC offset circuit 3335. DC offset circuit 3335 is configured to 10 adjustably (either automatically and/or manually via, for example, a potentiometer 3337) increase or decrease the DC bias of the cosine waves generated by cosine wave circuit 330 to simulate a short circuit condition or a non-short circuit condition. [0038] The output of adder 3330 is coupled to a buffer 3348 and coupled to a phase shift circuit 3354. Buffer 3348 is configured to the amplify signals received from adder 3330, and the output of buffer 3348 is coupled to an output 3340 of cosine wave circuit 330. [0039] Phase shift circuit 3354 is configured to shift the phase of the signals received from adder 3330 by 180°, and the output of phase shift circuit 3354 is coupled to another output 3350 of cosine wave circuit 330. [0040] As discussed above, resolver simulator 300 includes a reference voltage 340 selectively coupled to buffer 3220 and buffer 3320 via switches 3215 and 3315, respectively. Reference voltage 340 operates to simulate a motor at rest (i.e., rotating at zero RPMs). Because of reference voltage 340 and waveform generator 310, resolver simulator 300 is capable of simulating motor speeds from zero RPMs to speeds greater than, for example, 13,000 RPMs. This enables resolver simulator 300 to simulate the range of speeds of motor-resolver systems 100 and 150 (see FIG. 1). [0041] Resolver simulator 300 also includes a gain circuit 350 coupled to signal multiplier circuit 3225 and coupled to signal multiplier circuit 3325. Gain circuit 350 is configured to adjust (automatically and/or manually) the voltage amplitudes of the sine waves produced by sine wave circuit 320 and the cosine waves produced by cosine wave circuit 330. That is, gain circuit 350 is capable of adjusting the peak-to-peak voltage amplitudes of the sine waves and/or the cosine waves to simulate degraded signal fault conditions and/or loss of signal fault conditions depending upon whether the peak-to- peak amplitudes are greater than a maximum threshold voltage amplitude or less than a minimum threshold voltage amplitude. Moreover, gain circuit 350 11 is capable of manipulating the peak-to-peak voltage amplitudes of the sine waves and/or the cosine waves to simulate a "properly functioning" signal. [0042] To accomplish such, gain circuit 350 includes a buffer 3510 coupled to signal multiplier circuits 3225 and 3325 discussed above. Gain circuit 350 also includes buffer 3510 coupled to a differential amplifier 3520. Moreover, differential amplifier 3520 includes a positive excitation input 3524 and a negative excitation input 3528 of resolver decoders 105 and 155 (see FIG. 1). [0043] Resolver simulator 300 also includes a resolver decoder 360 for self- calibrating resolver simulator 300 prior to testing a motor controller (e.g., motor controller 120). Resolver decoder 360 is configured to be substantially similar to resolver decoders 1250 and 1275 (see FIG. 1). To self-calibrate resolver simulator 300, waveform generator 310, DC offset circuit 3235, DC offset circuit 3335, and gain circuit 350 are each adjusted so that resolver simulator 300 does not produce one or more fault conditions. That is, resolver simulator 300 outputs signals from sine wave circuit 320 and cosine wave circuit 330 to resolver decoder 360 representing a correctly functioning motor. Because resolver decoder 360 is substantially similar to resolver decoders 1250 and 1275, resolver simulator 300 is also calibrated for motor controller 120. [0044] As illustrated in FIG. 3, sine wave output 3240 is selectively coupled to the input of resolver decoder 360 or one resolver decoder (e.g., resolver decoders 1250 and 1275) of motor controller 120 via a switch 365 (e.g., an SPDT switch). Similarly, sine wave output 3250 is selectively coupled to the input of resolver decoder 360 or to one resolver decoder of motor controller 120 via a switch 370 (e.g., an SPDT switch). [0045] Cosine wave output 3340 is selectively coupled to the input of resolver decoder 360 or to one resolver decoder of motor controller 120 via a switch 375 (e.g., an SPDT switch). Furthermore, cosine wave output 3350 is selectively coupled to the input of resolver decoder 360 or to one resolver 12 decoder of motor controller 120 via a switch 380 (e.g., an SPDT switch). That is, sine wave output 3240, sine wave output 3250, cosine wave output 3340, and cosine wave output 3350 are coupled to the input of resolver decoder 360 when resolver simulator 300 is being self-calibrated, and coupled to either resolver decoder 1250 or 1275 when resolver simulator 300 is testing resolver decoder 1250 or 1275, respectively. [0046] In addition, positive excitation input 3524 is selectively coupled to the output of resolver decoder 360 or the output of one resolver decoder of motor controller 120 via a switch 385 (e.g., an SPDT switch). Negative excitation input 3528 is selectively coupled to the output of resolver decoder 360 or the output of one resolver decoder of motor controller 120 via a switch 390 (e.g., an SPDT switch). That is, positive excitation input 3524 and negative excitation input 3528 are coupled to the output of resolver decoder 360 when resolver simulator 300 is being self-calibrated, and coupled to the output of either resolver decoder 1250 or 1275 when resolver simulator 300 is testing resolver decoder 1250 or 1275, respectively. [0047\| During an exemplary operational mode, various inputs to resolver simulator 300 may be manually and/or automatically adjusted to simulate one or more of the fault conditions discussed above or a properly operating condition to determine if the motor controller (e.g., motor controller 120) is functioning properly. For example, the frequency of signals produced by waveform generator 310 may be increased so that the outputs of sine wave output 3240, sine wave output 3250, cosine wave output 3340, and/or cosine wave output 3350 simulate a loss of tracking fault condition. In another example, the DC bias of the outputs of sine wave output 3240 and sine wave output 3250, and/or cosine wave output 3340 and cosine wave output 3350 may be adjusted to be too high or too low to simulate a short circuit fault condition. Furthermore, the voltage gain produced by gain circuit 350 may be increased or decreased so that the peak-to-peak voltage amplitude of the 13 outputs of sine wave output 3240, sine wave output 3250, cosine wave output 3340, and/or cosine wave output 3350 are less than or greater than a pre- determined threshold to simulate a loss of signal or degraded signal fault condition, respectively. In addition, the outputs may include a frequency, DC bias, and peak-to-peak voltage simulating a properly functioning motor- resolver system. Accordingly, resolver simulator 300 is capable of simulating the multiple fault conditions discussed above with reference to motor-resolver systems 100 and 150, as well as a properly functioning motor-resolver system. [0048] FIG. 4 is a flow diagram representing one exemplary embodiment of a method 400 for testing system 10. After system 10 is coupled to device 200 (e.g., resolver 105 is coupled to connector 202, resolver 155 is coupled to connector 204, resolver decoder 1250 is coupled to connector 206, and resolver decoder 1275 is coupled to connector 208), resolver 105 is coupled to resolver decoder 1250 via, for example, swapping circuits 210 and 220. A signal from resolver 105 is transmitted to resolver decoder 1250 (step 405) to determine if motor controller 120 transmits an error message in response to the signal from resolver 105 (step 410). [0049] Resolver 155 is coupled to resolver decoder 1275 via, for example, swapping circuits 230 and 240. A signal from resolver 155 is transmitted to resolver decoder 1275 (step 415) to determine if motor controller 120 transmits an error message in response to the signal from resolver 155 (step 420). [0050] Resolver 105 is also coupled to resolver decoder 1275 via, for example, swapping circuits 210 and 220. A signal from resolver 105 is transmitted to resolver decoder 1275 (step 425) to determine if motor controller 120 transmits an error message in response to the signal from resolver 105 (step 430). Similarly, resolver 155 is also coupled to resolver decoder 1250 via, for example, swapping circuits 230 and 240. A signal from resolver 155 is transmitted to resolver decoder 1250 (step 435) to determine if 14 motor controller 120 transmits an error message in response to the signal from resolver 155 (step 440). [0051] Once steps 405 through 440 have been performed, it can be determined which of resolver 105, resolver 155, resolver decoder 1250, resolver decoder 1275, and/or an input/output (I/O) or software of motor controller 120 is malfunctioning (step 445). Resolver 105 and/or 155 is malfunctioning if motor controller 120 transmits an error message that "jumps" from one decoder to the other decoder when motor controller 120 receives signals from resolver 105 or 155, respectively. For example, if motor controller 120 transmits an error message when resolver decoder 1250 is receiving signals from resolver 105 (via swapping circuits 210 and 220), and also transmits an error message when resolver decoder 1275 is receiving signals from resolver 105 (after swapping circuit 220 connects to resolver decoder 1275), resolver 105 is malfunctioning. In another example, if motor controller 120 transmits an error message when resolver decoder 1275 is receiving signals from resolver 155 (via swapping circuits 230 and 240), and also transmits an error message when resolver decoder 1250 is receiving signals from resolver 155 (after swapping circuit 240 connects to resolver decoder 1275), resolver 155 is malfunctioning. [0052] Resolver decoder 1250 or 1275 (or an I/O or software of motor controller 120) is malfunctioning if motor controller 120 transmits an error message that fails to "jump" from one resolver decoder to the other resolver decoder when resolver decoders 1250 and 1275 receive signals from resolvers 105 and 155, respectively. For example, if motor controller 120 transmits an error message when resolver decoder 1250 is receiving signals from resolver 105 (via swapping circuits 210 and 220), and continues to transmit an error message when resolver decoder 1250 is receiving signals from resolver 155 (via swapping circuits 230 and 240), resolver decoder 1250 is malfunctioning. Likewise, if motor controller 120 transmits an error message when resolver 15 decoder 1275 is receiving signals from resolver 105 (via swapping circuits 210 and 220), and continues to transmit an error message when resolver decoder 1275 is receiving signals from resolver 155 (via swapping circuits 230 and 240), resolver decoder 1275 is malfunctioning. If resolver 105, resolver 155, resolver decoder 1250, and resolver decoder 1275 are each functioning properly, but motor controller 120 continues to transmit an error signal, an I/O or the software of motor controller 120 is malfunctioning. [0053] When resolver decoder 1250 or 1275 is malfunctioning, the type of malfunction resolver decoder 1250 or 1275 is experiencing can be determined (step 450). That is, resolver simulator 300 (and swapping circuits 210 and 230, as controlled by controller 250) may be used to identify which faulty condition(s) resolver decoder 1250 or 1275 is experiencing. [0054] To determine if the malfunction resolver decoder 1250 or 1275 is experiencing is associated with detection of a loss of tracking fault condition, resolver simulator 300 (after being coupled to resolver decoder 1250 or 1275) transmits one or more signals simulating a motor rate of speed. The speed may then be increased (either instantaneously or gradually) to simulate an acceleration that is too large or a rate of speed greater than a maximum threshold speed to determine if motor controller transmits an error message in response thereto. If motor controller 120 transmits an error message in response to the simulated speed being greater than the maximum threshold speed, resolver decoder 1250 or 1275 is not experiencing a malfunction associated with detecting a loss of tracking fault condition. Alternatively, if motor controller 120 fails to transmit an error message in response to the simulated speed being greater than the maximum threshold speed, resolver decoder 1250 or 1275 is experiencing a malfunction associated with detecting a loss of tracking fault condition. 16 [0055] In determining if the malfunction resolver decoder 1250 or 1275 is experiencing is associated with detection of a degraded signal fault condition, resolver simulator 300 transmits one or more signals simulating a resolver peak-to-peak voltage amplitude. The voltage of the simulated signals may initially simulate a properly functioning resolver. The voltage may then be increased (either instantaneously or gradually) to simulate a peak-to-peak voltage greater than a maximum threshold voltage to determine if motor controller transmits an error message in response to the simulated voltage being greater than the maximum threshold voltage. If motor controller 120 transmits an error message in response to the simulated voltage being greater than the maximum threshold voltage, resolver decoder 1250 or 1275 is not experiencing a malfunction associated with detecting a degraded signal fault condition. Alternatively, if motor controller 120 fails to transmit an error message in response to the simulated voltage being greater than the maximum threshold voltage, resolver decoder 1250 or 1275 is experiencing a malfunction associated with detecting a degraded signal fault condition. [0056] To determine if the malfunction resolver decoder 1250 or 1275 is experiencing is associated with detection of a loss of signal fault condition, resolver simulator 300 transmits one or more signals simulating a resolver peak-to-peak voltage amplitude. The voltage of the simulated signals may initially be within the range of voltages simulating a properly functioning resolver. The voltage may then be decreased (either instantaneously or gradually) to simulate a peak-to-peak voltage less than a minimum threshold voltage to determine if motor controller transmits an error message in response to the simulated voltage being less than the minimum threshold voltage. If motor controller 120 transmits an error message in response to the simulated voltage being less than the minimum threshold voltage, resolver decoder 1250 or 1275 is not experiencing a malfunction associated with detecting a loss of signal fault condition. Alternatively, if motor controller 120 fails to transmit 17 an error message in response to the simulated voltage being less than the minimum threshold voltage, resolver decoder 1250 or 1275 is experiencing a malfunction associated with detecting a loss of signal fault condition. [0057] In determining if the malfunction resolver decoder 1250 or 1275 is experiencing is associated with detection of a DC bias OOR fault condition, resolver simulator 300 transmits one or more signals simulating a resolver DC bias. The DC bias of the simulated signals may initially be within a range of DC biases simulating a properly functioning resolver. The DC bias may then be increased (either instantaneously or gradually) and/or decreased (either instantaneously or gradually) to simulate a DC bias that is either greater than a maximum threshold DC bias or a DC bias that is below a minimum threshold DC bias to determine if motor controller transmits an error message in response thereto. If motor controller 120 transmits an error message in response to the simulated DC bias being greater than the maximum threshold DC bias and/or (depending upon whether testing one of or both of the maximum and minimum DC bias threshold(s)) being less than the minimum threshold DC bias, resolver decoder 1250 or 1275 is not experiencing a malfunction associated with detecting a DC bias OOR fault condition. Alternatively, if motor controller 120 fails to transmit an error message in response to the simulated DC bias being greater than the maximum threshold DC bias and/or (depending upon whether testing one of or both of the maximum and minimum DC bias threshold(s)) being less than the minimum threshold DC bias, resolver decoder 1250 or 1275 is experiencing a malfunction associated with detecting a DC bias OOR fault condition. [0058] After the type of malfunction is determined, the magnitude of the malfunction can be quantified (step 455). The magnitude of the malfunction may be quantified by determining a threshold motor speed (for a loss of tracking fault condition), a threshold peak-to-peak voltage (for a loss of signal 18 fault condition or a degraded signal condition), or a DC bias threshold (for a DC bias OOR fault condition). [0059] The threshold motor speed is the motor speed at which motor controller 120 transmits the error message in response to signals from resolver simulator 300. To determine the threshold motor speed when a loss of tracking fault condition exists, waveform generator 310 (see FIG. 3) may be adjusted (either gradually or instantaneously) so that resolver simulator 300 outputs signals simulating varying motor speeds until motor controller 120 transmits the error signal. The simulated motor speed may be started at a speed representing a properly functioning resolver signal or a speed representing the loss of tracking fault condition. The threshold motor speed may then be compared to the motor speed at which motor controller 120 should transmit the error message to quantify the loss of tracking fault condition. [0060] The threshold peak-to-peak voltage is the voltage at which at which motor controller 120 transmits the error message in response to signals from resolver simulator 300. In determining the threshold peak-to-peak voltage when a degraded signal fault condition exists, gain circuit 350 (see FIG. 3) may be adjusted (either gradually or instantaneously) so that resolver simulator 300 outputs signals simulating varying peak-to-peak voltages until motor controller 120 transmits the error signal. The simulated peak-to-peak voltages may be started at a voltage representing a properly functioning resolver signal or a voltage representing the degraded signal fault condition. The threshold voltage may then be compared to the voltage at which motor controller 120 should transmit the error message to quantify the degraded signal fault condition. Similarly, gain circuit 350 may be adjusted (either gradually or instantaneously) so that resolver simulator 300 outputs signals simulating varying peak-to-peak voltages to determine the threshold peak-to- peak voltage when a loss of signal fault condition exists. 19 [0061] The threshold DC bias is the DC bias at which at which motor controller 120 transmits the error message in response to signals from resolver simulator 300. In determining the threshold DC bias when a DC bias OOR fault condition exists, DC offset circuit 3235 and/or DC offset circuit 3335 (see FIG. 3) may be adjusted (either gradually or instantaneously) so that resolver simulator 300 outputs signals simulating varying DC biases until motor controller 120 transmits the error signal. The simulated DC biases may be started at a DC bias representing a properly functioning resolver signal or a DC bias representing the short circuit fault condition. The threshold DC bias may then be compared to the DC bias at which motor controller 120 should transmit the error message to quantify the short circuit fault condition. [0062] Sometimes when a malfunction exists in system 10, which of motor- resolver systems 100 and 150 has the problem is known. However, whether the malfunction is on the motor side or the motor controller side is unknown. For example, if a malfunction exists in system 10, it may be known that the malfunction is within motor-resolver system 100, however; whether resolver 105 or resolver decoder 1250 is the malfunctioning component is unknown. In another example, if a malfunction exists in system 10, it may be known that the malfunction is within motor-resolver system 150, however; whether resolver 155 or resolver decoder 1275 is the malfunctioning component is unknown. [0063] FIG. 5 is a flow diagram representing one exemplary embodiment of a method 500 for diagnosing faults in system 10 when it is known that the malfunction is in motor-resolver system 100 or motor-resolver system 150. Method 500 begins by coupling a resolver (e.g., resolver 105) to a resolver decoder (e.g., resolver decoder 1275) (step 505), and coupling another resolver (e.g., resolver 155) to another resolver decoder (e.g., resolver decoder 1250) (step 510). A signal is transmitted from resolver 105 to resolver decoder 1275 (step 515) to determine if the motor controller (e.g., motor controller 120) 20 transmits an error message (step 520). A signal is also transmitted from resolver 155 to resolver decoder 1250 (step 525) to determine motor controller 120 transmits an error message (step 530). [0064] Once steps 505 through 525 have been performed, which motor controller or resolver decoder is malfunctioning can be determined (step 535). If the error message transmitted by motor controller 120 "jumps" from one resolver decoder to the other resolver decoder, the motor is malfunctioning. If the error message fails to jump from one resolver decoder to the other resolver decoder (i.e., stays at the same resolver decoder), the resolver decoder is malfunctioning. For example, if it is known that motor-resolver system 100 is malfunctioning, after resolver 105 transmits a signal to resolver decoder 1275 and resolver 155 transmits a signal to resolver decoder 1250, if controller 120 transmits the error message from resolver decoder 1275, resolver 105 is malfunctioning. If controller 120 transmits the error message from resolver decoder 1250, resolver decoder 1250 is malfunctioning. In an example when it is known that motor-resolver system 150 is malfunctioning, if controller 120 transmits the error message from resolver decoder 1250, resolver 155 is malfunctioning; but if controller 120 transmits the error message from resolver decoder 1275, resolver decoder 1275 is malfunctioning. [0065] When resolver decoder 1250 or 1275 is malfunctioning, which of the multiple fault conditions resolver decoder 1250 or 1275 is experiencing can be determined in a manner similar to step 450 discussed above with respect to FIG. 4 (step 540). Furthermore, once the type of fault condition is determined, the magnitude of the fault condition(s) can be determined in a manner similar to step 455 discussed above with respect to FIG. 4 (step 545). 21 [0066] FIG. 6 is a flow diagram representing one exemplary embodiment of a method 600 for diagnosing faults in system 10. Method 600 begins by knowing that a motor controller (e.g., motor controller 120) indicates that side A (e.g., motor-resolver system 100 in FIG. 1) and side B (e.g., motor-resolver system 150 in FIG. 1) of system 10 are malfunctioning (i.e., are "bad") (step 605). [0067] Method 600 also includes connecting system 10 to device 200 and swapping (via swapping circuits 220 and 240) the coupling of sides A and B (step 610). That is, for example, coupling resolver 105 to decoder resolver 1275 and coupling resolver 155 to resolver decoder 1250 when resolver 105 was initially coupled to resolver decoder 1250 and resolver 155 was initially coupled to resolver decoder 1275. [0068] Side A is checked to determine if it is functioning properly (i.e., if it is "good") and side B is checked to determine if it is malfunctioning or bad (step 615). If side A is functioning properly and side B is malfunctioning, decoder A (e.g., resolver decoder 1250) and resolver B (e.g., resolver 155) are determined to be functioning properly (i.e., are "good") (step 620), and decoder B (e.g., resolver decoder 1275) and resolver A (e.g., resolver 105) are determined to be malfunctioning (i.e., are "bad") (step 625). [0069] Side A is checked to determine if it is malfunctioning and side B is checked to determine if it is functioning properly (step 630). If side A is malfunctioning and side B is functioning properly, decoder B (e.g., resolver decoder 1275) and resolver A (e.g., resolver 105) are determined to be functioning properly (i.e., are "good") (step 635), and decoder A (e.g., resolver decoder 1250) and resolver B (e.g., resolver 155) are determined to be malfunctioning (i.e., are "bad") (step 640). [0070] If the answer to both steps 615 and 630 are NO, it is determined that resolvers A and B, or decoders A and B are both malfunctioning (step 645). In this situation, a resolver simulator (e.g., resolver simulator 300) is used to 22 check decoders A and B (step 650) to determine if decoders A and B are both functioning properly (step 655). If decoders A and B are functioning properly, resolvers A and B are both malfunctioning (step 660); otherwise, decoders A and B are both malfunctioning (step 665). [0071] While at least one exemplary embodiment has been presented in the foregoing detailed description of the invention, it should be appreciated that a vast number of variations exist and that the method steps described with reference to FIGS. 4 and 5 may be performed in any order and/or one or more steps may be omitted. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention, it being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the invention as set forth in the appended claims and their legal equivalents. 23 CLAIMS We claim: 1. A system for diagnosing faults in multiple, associated motor-resolver systems including a first resolver, a second resolver, and a motor controller including a first decoder and a second decoder, the system comprising: 5 a first swapping circuit selectively coupling the first resolver to one of the first decoder and the second decoder; and a second swapping circuit selectively coupling the second resolver to one of the first decoder and the second decoder. 2. The system of claim 1, further comprising: an adjustable resolver simulator configured to generate outputs simulating at least one resolver fault condition of a plurality of resolver fault conditions; and 5 a third swapping circuit selectively coupling one of the resolver simulator and the first resolver to the first swapping circuit. 3. The system of claim 2, further comprising a fourth swapping circuit selectively coupling one of the resolver simulator and the second resolver to the second swapping circuit. 4. The system of claim 1, further comprising: an adjustable resolver simulator configured to generate outputs simulating at least one resolver fault condition of a plurality of resolver fault conditions; and 5 a third swapping circuit selectively coupling one of the resolver simulator and the second resolver to the second swapping circuit. 24 5. A method for diagnosing faults in multiple, associated motor-resolver systems including (i) a first motor rcsolver that transmits a first resolver signal to a first decoder and (ii) a second motor resolver that transmits a second resolver signal to a second decoder, wherein the first and second decoders are each configured to 5 detect fault conditions represented in the first and second resolver signals, respectively, and configured to generate a first and second fault signal, respectively, in response to detecting a fault condition, and wherein the first fault signal has been generated, the method comprising the steps of: applying the second signal to the first decoder to determine that the first 10 decoder is malfunctioning if the first decoder continues to generate the first fault signal; and applying the first signal to the second decoder to determine that the first motor is malfunctioning if the second decoder generates the second fault signal. 6. The method of claim 5, wherein the first decoder includes a malfunction, the method further comprising the step of determining a type of the fault condition causing the malfunction. 7. The method of claim 6, further comprising the step of quantifying a threshold of the fault condition. 8. The method of claim 7, wherein the quantifying step comprises the steps of: transmitting a plurality of signals simulating varying rates of speeds to the first decoder; and 5 identifying a rate of speed that causes the motor controller to transmit the first fault signal in response to the plurality of signals. 25 9. The method of claim 7, wherein the quantifying step comprises the steps of: transmitting a plurality of signals simulating varying DC biases; and identifying a DC bias that causes the motor controller to transmit the 5 first fault signal in response to the plurality of signals. 10. The method of claim 7, wherein the quantifying step comprises the steps of: transmitting a plurality of signals simulating varying peak-to-peak voltage amplitudes greater than a maximum threshold voltage; and 5 identifying a voltage that causes the motor controller to transmit the error message in response to the plurality of signals. 11. The method of claim 7, wherein the quantifying step comprises the steps of: transmitting a plurality of signals simulating varying peak-to-peak voltage amplitudes less than a minimum threshold voltage; and 5 identifying a voltage that causes the motor controller to transmit the error message in response to the plurality of signals. 12. A method for diagnosing faults in multiple, associated motor-resolver systems including a first motor having an associated first resolver, a second motor having an associated second resolver, and a motor controller having a first decoder and a second decoder, the method comprising the steps of: 5 transmitting a first signal from the first resolver to the first decoder; transmitting a second signal from the second resolver to the second decoder; transmitting a third signal from the first resolver to the second decoder; 26 10 transmitting a fourth signal from the second resolver to the first decoder; and determining if one of the first decoder, the second decoder, the first motor, and the second motor is malfunctioning. 13. The method of claim 12, wherein the determining step comprises the steps of: determining if the motor controller transmits an error message in response to one of the first signal and the second signal; and 5 determining if the motor controller transmits the error message in response to one of the third signal and the fourth signal. 14. The method of claim 13, the method further comprising the steps of: determining that the first motor is malfunctioning if the motor controller transmits the error message in response to both the first signal and the third signal; 5 determining that the second motor is malfunctioning if the motor controller transmits the error message in response to both the second signal and the fourth signal. 15. The method of claim 13, further comprising the steps of: determining that the first decoder is malfunctioning if the motor controller transmits the error message in response to both the first signal and the fourth signal; and 5 determining that the second decoder is malfunctioning if the motor controller transmits the error message in response to both the second signal and the third signal. 27 16. The method of claim 15, wherein one of the first decoder and the second decoder includes a malfunction, the method further comprising the step of determining a type of fault condition causing the malfunction from a group of fault conditions comprised of a loss of tracking fault condition, a loss of signal fault 5 condition, a short circuit fault condition, and a degraded signal fault condition. 17. The method of claim 16, further comprising the step of quantifying a threshold of the one of the loss of tracking fault condition, the loss of signal fault condition, the degraded signal fault condition, and the short circuit fault condition. 18. The method of claim 17, wherein the quantifying step comprises the steps of: transmitting a plurality of signals simulating varying rates of speeds to the first decoder; and 5 identifying a rate of speed that causes the motor controller to transmit the error message in response to the plurality of signals. 19. The method of claim 17, wherein the quantifying step comprises the steps of: transmitting a plurality of signals simulating varying DC biases; and identifying a DC bias that causes the motor controller to transmit the 5 error message in response to the plurality of signals. 28 20. The method of claim 17, wherein the quantifying step comprises the steps of: transmitting a plurality of signals simulating varying peak-to-peak voltage amplitudes one of greater than a maximum threshold voltage and less than a 5 minimum threshold voltage; and identifying a voltage that causes the motor controller to transmit the error message in response to the plurality of signals. Apparatus and methods are provided for diagnosing faults in multiple, associated motor-resolver systems. One apparatus includes a swapping circuit coupling a first resolver to a first or second decoder, and a swapping circuit coupling a second resolver to the first or second decoder. One method includes applying a signal from a resolver to a first decoder to determine that the first decoder is lfunctioning if the first decoder continues to generate a fault signal, and applying a signal from a different resolver to a second decoder to determine that a motor associated with the first decoder is malfunctioning if the second decoder generates a fault signal. Another method includes transmitting a signal from a resolver to first and second decoders, transmitting a signal from a different resolver to the first and second decoders, and determining if the first decoder, second decoder, a first motor, or a second motor is malfunctioning.

Full Text

1
APPARATUS AND METHODS FOR DIAGNOSING
MOTOR-RESOLVER SYSTEM FAULTS
FIELD OF THE INVENTION
[00011 The present invention generally relates to motor-resolver systems,
and more particularly relates to apparatus and methods for diagnosing faults in
multiple, associated motor-resolver systems.
BACKGROUND OF THE INVENTION
[0002] Motor-resolver systems are typically employed to accurately sense
and control the position of rotating shafts. As a motor is employed to a
resolvcr at a particular rate or rotational velocity, the output of the resolver is
then fed to a motor controller to determine if the motor is properly driving the
shafts. When a resolver anomaly is detected, the motor controller notifies the
user with an error message (e.g., a visual warning, an audio warning, etc.).
[0003] Some devices (e.g., a hybrid vehicle) include multiple motors (and
multiple resolvers) coupled to a single motor controller. In these devices, the
motor controller often includes a resolver decoder for each respective resolver.
For example, a hybrid vehicle includes a first motor for operation with the
electric portion of the vehicle, and a second motor for operation with the
combustion portion of the vehicle. The resolver associated with the first
motor is coupled to a first resolver decoder, and the resolver associated with
the second motor is coupled to a second resolver decoder within the common
motor controller.
[0004] There are times, however, when one of the resolvers is
malfunctioning and the motor controller transmits a warning to the user
indicating that the motor coupled to the malfunctioning resolver is not
working properly when in fact, it is the resolver decoder that is not working
properly. Thus, it is often difficult to determine which of the resolver or the

2
resolver decoder is malfunctioning when the motor controller transmits an
error message.
[0005] Since replacing a motor (and resolver) or a motor controller are
expensive, it is desirable to provide efficient systems and methods for testing a
motor (via its resolver) and a resolver decoder coupled to the resolver to
determine which of the motor/resolver and the motor controller is
malfunctioning when the motor controller transmits an error message without
replacing the motor or motor controller of a vehicle system (e.g., a hybrid
vehicle system). Furthermore, other desirable features and characteristics of
the present invention will become apparent from the subsequent detailed
description of the invention and the appended claims, taken in conjunction
with the accompanying drawings and this background of the invention.
BRIEF SUMMARY OF THE INVENTION
[0006] Various exemplary embodiments of the invention provide apparatus
and methods for diagnosing faults in multiple, associated motor-resolver
systems. For multiple, associated motor-resolver systems including a first
resolver, a second resolver, and a motor controller including a first decoder
and a second decoder, one system includes a first swapping circuit selectively
coupling the first resolver to the first decoder or the second decoder, and a
second swapping circuit selectively coupling the second resolver to the first
decoder or the second decoder.
[0007] For multiple, associated motor-resolver systems including (i) a first
motor resolver that transmits a first resolver signal to a first decoder and (ii) a
second motor resolver that transmits a second resolver signal to a second
decoder, wherein the first and second decoders are each configured to detect
fault conditions represented in the first and second resolver signals,
respectively, and configured to generate a first and second fault signal,
respectively, in response to detecting a fault condition, and wherein the first

3
fault signal has been generated, one method for diagnosing faults includes the
step of applying the second signal to the first decoder to determine that the
first decoder is malfunctioning if the first decoder continues to generate the
first fault signal. This method also includes the step of applying the first
signal to the second decoder to determine that the first motor is malfunctioning
if the second decoder generates the second fault signal.
[0008] One method for diagnosing faults in multiple, associated motor-
resolver systems including a first motor having an associated first resolver, a
second motor having a second associated resolver, and a motor controller
having a first decoder and a second decoder includes the steps of transmitting
a first signal from the first resolver to the first decoder and transmitting a
second signal from the second resolver to the second decoder. This method
also includes the steps of transmitting a third signal from the first resolver to
the second decoder and transmitting a fourth signal from the second resolver
to the first decoder. After the first, second, third, and fourth signals are
transmitted, which of the first decoder, the second decoder, the first motor, or
the second motor is malfunctioning can be determined.
BRIEF DESCRIPTION OF THE DRAWINGS
[0009] The present invention will hereinafter be described in conjunction
with the following drawing figures, wherein like numerals denote like
elements, and
[0010] FIG. 1 is a schematic diagram of a prior art system having multiple,
associated motor-resolver systems;
[0011] FIG. 2 is a schematic diagram of an exemplary embodiment of a
device for diagnosing faults in the system of FIG. 1;
[0012] FIG. 3 is a schematic diagram of one exemplary embodiment of a
resolver simulator included in the device of FIG. 2;

4
[0013] FIG. 4 is a flow diagram representing one exemplary embodiment of
a method for diagnosing faults in the system of FIG. 1;
[0014] FIG. 5 is a flow diagram representing another exemplary
embodiment of a method for diagnosing faults in the system of FIG. 1; and
[0015] FIG. 6 is a flow diagram representing yet another exemplary
embodiment of a method for diagnosing faults in the system of FIG. 1.
DETAILED DESCRIPTION OF THE INVENTION
[0016] The following detailed description of the invention is merely
exemplary in nature and is not intended to limit the invention or the
application and uses of the invention. Furthermore, there is no intention to be
bound by any theory presented in the preceding background of the invention
or the following detailed description of the invention.
[0017] FIG. 1 is a schematic of a prior art system 10 including a motor-
resolver system 100 and a motor-resolver system 150. Motor-resolver system
100 includes a resolver 105 coupled to a motor 110. Resolver 105 is
configured to transmit signals representing the operating characteristics (e.g.,
motor speed, rotor angle, signal strength, connectivity, etc.) of motor 110 to a
motor controller 120.
[0018] Similarly, motor-resolver system 150 includes a resolver 155 coupled
to a motor 160. Resolver 155 is also configured to transmit signals
representing the operating characteristics of motor 160 to motor controller
120.
[0019] Motor controller 120 includes a resolver decoder 1250 for receiving
signals from resolver 105 and a resolver decoder 1275 for receiving signals
from resolver 155. Resolver decoders 1250 and 1275 are each configured to
monitor the operating characteristics of their respective motors (via resolvers
150 and 155) and transmit an error message when motor 110 or 160 are
malfunctioning, respectively.

5
[0020] When malfunctioning, motor 110 and 160 may exhibit at least one of
multiple possible fault conditions. One fault condition occurs when motors
110 and 160 are rotating too fast. This fault condition is referred to as a "loss
of tracking" condition. A loss of tracking condition is detected by resolver
decoders 1250 and 1275 when the frequency of the signals transmitted from
resolver 105 and/or 155 is greater than a pre-determined threshold frequency
of the signals or the resolver signal shows an exceedingly large rotational
acceleration.
[0021] A "degraded signal" is another fault condition that may occur in
motors 110 and 160. A degraded signal condition is detected by resolver
decoders 1250 and 1275 when the peak-to-peak voltage amplitude of the
signals transmitted from resolvers 105 and 155 are greater than a pre-
determined threshold voltage. Since each resolver typically includes two sine
wave feedback outputs and two cosine feedback outputs, the degraded signal
may be found from either the sine or cosine feedback signals. Additionally, if
the difference between the peak-to-peak voltage amplitudes of the sine and
cosine signals is greater than a pre-determined value, the degraded signal fault
may be logged by the corresponding resolver decoder.
[0022] Another fault condition that may be experienced by motors 110 and
160 is a "loss of signal" condition. A loss of signal fault condition is detected
by resolver decoders 1250 and 1275 when the peak-to-peak voltage amplitude
of the signals transmitted from resolvers 105 and/or 155 are less than a pre-
determined threshold. Since each resolver typically includes sine wave
feedback outputs and cosine feedback outputs, the loss of signal fault
conditions for each resolver may be caused by the loss of signal strength in
any of the feedback outputs, the extreme case being an open circuit in one or
more resolver wire connections.

6
[0023] A "DC bias Out-Of-Range (OOR)" condition is another fault
condition that may be experienced by resolvers 105 and 155. A DC bias OOR
fault condition is detected when the DC bias of the signals output by the pair
of sine wave feedback outputs and/or the pair of cosine wave feedback outputs
is either too high or too low. A short circuit condition to the power supply or
circuit ground is a typical DC bias OOR fault condition that may be
experienced by resolvers 105 and 155.
[0024] FIG. 2 is a schematic diagram of an exemplary embodiment of a
device 200 for diagnosing faults in system 10. Device 200 may be inserted in,
for example, a wire harness (not shown) between resolvers 105/155 and motor
controller 120. Device 200 includes a connector 202, a connector 204, a
connector 206, and a connector 208 to detachably couple device 200 to system
10. That is, connector 202 is configured to couple resolver 105 to device 200,
connector 204 is configured to couple resolver 155 to device 200, connector
206 is configured to couple resolver decoder 1250 to device 200, and
connector 208 is configured to couple resolver decoder 1275 to device 200.
[0025] Device 200 also includes a swapping circuit 210 coupled to a
swapping circuit 220. Swapping circuit 210 is configured to selectively switch
between being coupled to a resolver simulator 300 {see FIG. 3) and connector
202. Swapping circuit 220 is configured to selectively switch between being
coupled to connector 206 and connector 208. Accordingly, resolver simulator
300 or connector 202 may be coupled to either connector 206 or connector
208. Similarly, connector 206 or connector 208 may be coupled to either
resolver simulator 300 or connector 202.
[0026] Device 200 also includes a swapping circuit 230 coupled to a
swapping circuit 240. Swapping circuit 230 is configured to selectively switch
between being coupled to resolver simulator 300 or connector 204. Swapping
circuit 240 is configured to selectively switch between being coupled to
connector 206 or connector 208. Accordingly, resolver simulator 300 or

7
connector 204 may be coupled to either connector 206 or connector 208.
Similarly, connector 206 or connector 208 may be coupled to either resolver
simulator 300 or connector 204.
[0027] A controller 250 coupled to swapping circuits 210, 220, 230, and
240 is also included in device 200. Controller 250 is also coupled to a
connector 255 configured to detachably couple device 200 to motor controller
120.
[0028] Controller 250 is configured to operate in a plurality of modes (e.g., a
run/crank mode, an accessory mode, etc.) to test (discussed below) motor 110
(via resolver 105), motor 160 (via resolver 155), resolver decoder 1250, and/or
resolver decoder 1275. The accessory mode enables device 200 to "swap"
between the various components of device 200. That is, controller 250 is
configured to transmit a signal to swapping circuit 210, 220, 230, and/or 240
instructing one or more of these swapping circuits to switch from being
coupled to one component, to being coupled to another component. For
example, controller 250 may transmit a signal to swapping circuit 210 (when
the vehicle key is in the accessory position, but not in the run/crank position)
instructing swapping circuit 220 to switch from being coupled to connector
206 (i.e., resolver decoder 1250) to being coupled to connector 208 (i.e.,
resolver decoder 1275). Controller 250 may, at substantially the same time,
instruct swapping circuit 230 to switch from being coupled to connector 204
(i.e., resolver 155) to being coupled to resolver simulator 300. As one skilled
in the art will appreciate, controller 250 is able to transmit signals to swapping
circuit 210, 220, 230, and/or 240 to enable any combination of resolver
simulator 300, resolver 105, or resolver 155 to be coupled to resolver decoder
1250 or resolver decoder 1275 when operating in accessory mode.

8
[0029] In addition, controller 250 is configured to couple resolver simulator
300 to resolver decoder 1250 (via swapping circuits 210 and 220) and resolver
decoder 1275 (via swapping circuits 230 and 240) at the same time. Here,
resolver simulator 300 is capable of simulating both resolver 105 and resolver
155 to test resolver decoders 1250 and 1275 at the same time. That is,
controller 250 may couple resolver 105 and resolver 155 to a respective one of
resolver decoders 1250 and 1275, and then switch the coupling (via swapping
circuits 220 and 240) of resolver 105 and resolver 155 to the other one of
resolver decoders 1250 and 1275.
[0030] FIG. 3 is a schematic diagram of one exemplary embodiment of
resolver simulator 300 {see FIG. 2). Resolver simulator 300 includes an
adjustable waveform generator 310 configured to generate waveforms (e.g.,
square waves) representing an output of a motor (e.g., motor 110 or 160).
Moreover, the frequency of the signals generated by waveform generator 310
may be adjusted to simulate a "loss of tracking" fault condition of a motor
(i.e., the motor is rotating too fast) or normal speeds of a motor. The output of
waveform generator 310 is coupled to a sine wave circuit 320 and to a cosine
wave circuit 330.
[0031] Sine wave circuit 320 is configured to simulate a pair of sine wave
feedback outputs of resolvers 105 and 155. To accomplish this, sine wave
circuit 320 includes a low pass filter 3205 having an output coupled to a gain
adjustment circuit 3310. Low pass filter 3205 and gain adjustment circuit
3310 operate to transform the square waves generated by waveform generator
310 into sine waves.
[0032] Also included in sine wave circuit 320 is a switch 3215 (e.g., a single
pole, double throw (SPDT) switch) to selectively couple gain adjustment
circuit 3210 or a reference voltage 340 (discussed below) to a buffer 3320.
Sine wave circuit 320 also includes a signal multiplier circuit 3225 coupled to
the output of buffer 3220. The output of signal multiplier circuit 3225 is

9
coupled to an adder 3230, and adder 3230 is coupled to an adjustable DC
offset circuit 3235. DC offset circuit 3235 is configured to adjustably (either
automatically and/or manually via, for example, a potentiometer 3237)
increase or decrease the DC bias of the sine waves generated by sine wave
circuit 320 to simulate a short circuit condition or a non-short circuit
condition.
[0033] The output of adder 3230 is coupled to a buffer 3248 and to a phase
shift circuit 3254. Buffer 3248 is configured to the amplify signals received
from adder 3230, and the output of buffer 3248 is coupled to an output 3240 of
sine wave circuit 320.
[0034] Phase shift circuit 3254 is configured to shift the phase of the signals
received from adder 3230 by 180°, and the output of phase shift circuit 3254 is
coupled to another output 3250 of sine wave circuit 320.
[0035] Cosine wave circuit 330 is configured to simulate a pair of cosine
wave feedback outputs of resolvers 105 and 155. Cosine wave circuit 330
includes an output of a low pass filter 3305 coupled to a phase shift circuit
3307. The output of phase shift circuit 3307 is coupled to a gain adjustment
circuit 3310. Low pass filter 3305, phase shift circuit 3307, and gain
adjustment circuit 3310 operate to transform the square waves generated by
waveform generator 310 into sine waves (via low pass filter 3305) and then
into cosine waves (via phase shift circuit 3307).
[0036] Also included in cosine wave circuit 330 is a switch 3315 (e.g., a
single pole, double throw (SPDT) switch) to selectively couple the output of
gain adjustment circuit 3310 or a reference voltage 340 (discussed below) to a
buffer 3320.
[0037] Cosine wave circuit 330 also includes a signal multiplier circuit 3325
having an input coupled to buffer 3320. The output of signal multiplier circuit
3325 is coupled to an adder 3330, and adder 3330 is also coupled to an
adjustable DC offset circuit 3335. DC offset circuit 3335 is configured to

10
adjustably (either automatically and/or manually via, for example, a
potentiometer 3337) increase or decrease the DC bias of the cosine waves
generated by cosine wave circuit 330 to simulate a short circuit condition or a
non-short circuit condition.
[0038] The output of adder 3330 is coupled to a buffer 3348 and coupled to
a phase shift circuit 3354. Buffer 3348 is configured to the amplify signals
received from adder 3330, and the output of buffer 3348 is coupled to an
output 3340 of cosine wave circuit 330.
[0039] Phase shift circuit 3354 is configured to shift the phase of the signals
received from adder 3330 by 180°, and the output of phase shift circuit 3354 is
coupled to another output 3350 of cosine wave circuit 330.
[0040] As discussed above, resolver simulator 300 includes a reference
voltage 340 selectively coupled to buffer 3220 and buffer 3320 via switches
3215 and 3315, respectively. Reference voltage 340 operates to simulate a
motor at rest (i.e., rotating at zero RPMs). Because of reference voltage 340
and waveform generator 310, resolver simulator 300 is capable of simulating
motor speeds from zero RPMs to speeds greater than, for example, 13,000
RPMs. This enables resolver simulator 300 to simulate the range of speeds of
motor-resolver systems 100 and 150 (see FIG. 1).
[0041] Resolver simulator 300 also includes a gain circuit 350 coupled to
signal multiplier circuit 3225 and coupled to signal multiplier circuit 3325.
Gain circuit 350 is configured to adjust (automatically and/or manually) the
voltage amplitudes of the sine waves produced by sine wave circuit 320 and
the cosine waves produced by cosine wave circuit 330. That is, gain circuit
350 is capable of adjusting the peak-to-peak voltage amplitudes of the sine
waves and/or the cosine waves to simulate degraded signal fault conditions
and/or loss of signal fault conditions depending upon whether the peak-to-
peak amplitudes are greater than a maximum threshold voltage amplitude or
less than a minimum threshold voltage amplitude. Moreover, gain circuit 350

11
is capable of manipulating the peak-to-peak voltage amplitudes of the sine
waves and/or the cosine waves to simulate a "properly functioning" signal.
[0042] To accomplish such, gain circuit 350 includes a buffer 3510 coupled
to signal multiplier circuits 3225 and 3325 discussed above. Gain circuit 350
also includes buffer 3510 coupled to a differential amplifier 3520. Moreover,
differential amplifier 3520 includes a positive excitation input 3524 and a
negative excitation input 3528 of resolver decoders 105 and 155 (see FIG. 1).
[0043] Resolver simulator 300 also includes a resolver decoder 360 for self-
calibrating resolver simulator 300 prior to testing a motor controller (e.g.,
motor controller 120). Resolver decoder 360 is configured to be substantially
similar to resolver decoders 1250 and 1275 (see FIG. 1). To self-calibrate
resolver simulator 300, waveform generator 310, DC offset circuit 3235, DC
offset circuit 3335, and gain circuit 350 are each adjusted so that resolver
simulator 300 does not produce one or more fault conditions. That is, resolver
simulator 300 outputs signals from sine wave circuit 320 and cosine wave
circuit 330 to resolver decoder 360 representing a correctly functioning motor.
Because resolver decoder 360 is substantially similar to resolver decoders
1250 and 1275, resolver simulator 300 is also calibrated for motor controller
120.
[0044] As illustrated in FIG. 3, sine wave output 3240 is selectively coupled
to the input of resolver decoder 360 or one resolver decoder (e.g., resolver
decoders 1250 and 1275) of motor controller 120 via a switch 365 (e.g., an
SPDT switch). Similarly, sine wave output 3250 is selectively coupled to the
input of resolver decoder 360 or to one resolver decoder of motor controller
120 via a switch 370 (e.g., an SPDT switch).
[0045] Cosine wave output 3340 is selectively coupled to the input of
resolver decoder 360 or to one resolver decoder of motor controller 120 via a
switch 375 (e.g., an SPDT switch). Furthermore, cosine wave output 3350 is
selectively coupled to the input of resolver decoder 360 or to one resolver

12
decoder of motor controller 120 via a switch 380 (e.g., an SPDT switch). That
is, sine wave output 3240, sine wave output 3250, cosine wave output 3340,
and cosine wave output 3350 are coupled to the input of resolver decoder 360
when resolver simulator 300 is being self-calibrated, and coupled to either
resolver decoder 1250 or 1275 when resolver simulator 300 is testing resolver
decoder 1250 or 1275, respectively.
[0046] In addition, positive excitation input 3524 is selectively coupled to
the output of resolver decoder 360 or the output of one resolver decoder of
motor controller 120 via a switch 385 (e.g., an SPDT switch). Negative
excitation input 3528 is selectively coupled to the output of resolver decoder
360 or the output of one resolver decoder of motor controller 120 via a switch
390 (e.g., an SPDT switch). That is, positive excitation input 3524 and
negative excitation input 3528 are coupled to the output of resolver decoder
360 when resolver simulator 300 is being self-calibrated, and coupled to the
output of either resolver decoder 1250 or 1275 when resolver simulator 300 is
testing resolver decoder 1250 or 1275, respectively.
[0047| During an exemplary operational mode, various inputs to resolver
simulator 300 may be manually and/or automatically adjusted to simulate one
or more of the fault conditions discussed above or a properly operating
condition to determine if the motor controller (e.g., motor controller 120) is
functioning properly. For example, the frequency of signals produced by
waveform generator 310 may be increased so that the outputs of sine wave
output 3240, sine wave output 3250, cosine wave output 3340, and/or cosine
wave output 3350 simulate a loss of tracking fault condition. In another
example, the DC bias of the outputs of sine wave output 3240 and sine wave
output 3250, and/or cosine wave output 3340 and cosine wave output 3350
may be adjusted to be too high or too low to simulate a short circuit fault
condition. Furthermore, the voltage gain produced by gain circuit 350 may be
increased or decreased so that the peak-to-peak voltage amplitude of the

13
outputs of sine wave output 3240, sine wave output 3250, cosine wave output
3340, and/or cosine wave output 3350 are less than or greater than a pre-
determined threshold to simulate a loss of signal or degraded signal fault
condition, respectively. In addition, the outputs may include a frequency, DC
bias, and peak-to-peak voltage simulating a properly functioning motor-
resolver system. Accordingly, resolver simulator 300 is capable of simulating
the multiple fault conditions discussed above with reference to motor-resolver
systems 100 and 150, as well as a properly functioning motor-resolver system.
[0048] FIG. 4 is a flow diagram representing one exemplary embodiment of
a method 400 for testing system 10. After system 10 is coupled to device 200
(e.g., resolver 105 is coupled to connector 202, resolver 155 is coupled to
connector 204, resolver decoder 1250 is coupled to connector 206, and
resolver decoder 1275 is coupled to connector 208), resolver 105 is coupled to
resolver decoder 1250 via, for example, swapping circuits 210 and 220. A
signal from resolver 105 is transmitted to resolver decoder 1250 (step 405) to
determine if motor controller 120 transmits an error message in response to the
signal from resolver 105 (step 410).
[0049] Resolver 155 is coupled to resolver decoder 1275 via, for example,
swapping circuits 230 and 240. A signal from resolver 155 is transmitted to
resolver decoder 1275 (step 415) to determine if motor controller 120
transmits an error message in response to the signal from resolver 155 (step
420).
[0050] Resolver 105 is also coupled to resolver decoder 1275 via, for
example, swapping circuits 210 and 220. A signal from resolver 105 is
transmitted to resolver decoder 1275 (step 425) to determine if motor
controller 120 transmits an error message in response to the signal from
resolver 105 (step 430). Similarly, resolver 155 is also coupled to resolver
decoder 1250 via, for example, swapping circuits 230 and 240. A signal from
resolver 155 is transmitted to resolver decoder 1250 (step 435) to determine if

14
motor controller 120 transmits an error message in response to the signal from
resolver 155 (step 440).
[0051] Once steps 405 through 440 have been performed, it can be
determined which of resolver 105, resolver 155, resolver decoder 1250,
resolver decoder 1275, and/or an input/output (I/O) or software of motor
controller 120 is malfunctioning (step 445). Resolver 105 and/or 155 is
malfunctioning if motor controller 120 transmits an error message that
"jumps" from one decoder to the other decoder when motor controller 120
receives signals from resolver 105 or 155, respectively. For example, if motor
controller 120 transmits an error message when resolver decoder 1250 is
receiving signals from resolver 105 (via swapping circuits 210 and 220), and
also transmits an error message when resolver decoder 1275 is receiving
signals from resolver 105 (after swapping circuit 220 connects to resolver
decoder 1275), resolver 105 is malfunctioning. In another example, if motor
controller 120 transmits an error message when resolver decoder 1275 is
receiving signals from resolver 155 (via swapping circuits 230 and 240), and
also transmits an error message when resolver decoder 1250 is receiving
signals from resolver 155 (after swapping circuit 240 connects to resolver
decoder 1275), resolver 155 is malfunctioning.
[0052] Resolver decoder 1250 or 1275 (or an I/O or software of motor
controller 120) is malfunctioning if motor controller 120 transmits an error
message that fails to "jump" from one resolver decoder to the other resolver
decoder when resolver decoders 1250 and 1275 receive signals from resolvers
105 and 155, respectively. For example, if motor controller 120 transmits an
error message when resolver decoder 1250 is receiving signals from resolver
105 (via swapping circuits 210 and 220), and continues to transmit an error
message when resolver decoder 1250 is receiving signals from resolver 155
(via swapping circuits 230 and 240), resolver decoder 1250 is malfunctioning.
Likewise, if motor controller 120 transmits an error message when resolver

15
decoder 1275 is receiving signals from resolver 105 (via swapping circuits 210
and 220), and continues to transmit an error message when resolver decoder
1275 is receiving signals from resolver 155 (via swapping circuits 230 and
240), resolver decoder 1275 is malfunctioning. If resolver 105, resolver 155,
resolver decoder 1250, and resolver decoder 1275 are each functioning
properly, but motor controller 120 continues to transmit an error signal, an I/O
or the software of motor controller 120 is malfunctioning.
[0053] When resolver decoder 1250 or 1275 is malfunctioning, the type of
malfunction resolver decoder 1250 or 1275 is experiencing can be determined
(step 450). That is, resolver simulator 300 (and swapping circuits 210 and
230, as controlled by controller 250) may be used to identify which faulty
condition(s) resolver decoder 1250 or 1275 is experiencing.
[0054] To determine if the malfunction resolver decoder 1250 or 1275 is
experiencing is associated with detection of a loss of tracking fault condition,
resolver simulator 300 (after being coupled to resolver decoder 1250 or 1275)
transmits one or more signals simulating a motor rate of speed. The speed
may then be increased (either instantaneously or gradually) to simulate an
acceleration that is too large or a rate of speed greater than a maximum
threshold speed to determine if motor controller transmits an error message in
response thereto. If motor controller 120 transmits an error message in
response to the simulated speed being greater than the maximum threshold
speed, resolver decoder 1250 or 1275 is not experiencing a malfunction
associated with detecting a loss of tracking fault condition. Alternatively, if
motor controller 120 fails to transmit an error message in response to the
simulated speed being greater than the maximum threshold speed, resolver
decoder 1250 or 1275 is experiencing a malfunction associated with detecting
a loss of tracking fault condition.

16
[0055] In determining if the malfunction resolver decoder 1250 or 1275 is
experiencing is associated with detection of a degraded signal fault condition,
resolver simulator 300 transmits one or more signals simulating a resolver
peak-to-peak voltage amplitude. The voltage of the simulated signals may
initially simulate a properly functioning resolver. The voltage may then be
increased (either instantaneously or gradually) to simulate a peak-to-peak
voltage greater than a maximum threshold voltage to determine if motor
controller transmits an error message in response to the simulated voltage
being greater than the maximum threshold voltage. If motor controller 120
transmits an error message in response to the simulated voltage being greater
than the maximum threshold voltage, resolver decoder 1250 or 1275 is not
experiencing a malfunction associated with detecting a degraded signal fault
condition. Alternatively, if motor controller 120 fails to transmit an error
message in response to the simulated voltage being greater than the maximum
threshold voltage, resolver decoder 1250 or 1275 is experiencing a
malfunction associated with detecting a degraded signal fault condition.
[0056] To determine if the malfunction resolver decoder 1250 or 1275 is
experiencing is associated with detection of a loss of signal fault condition,
resolver simulator 300 transmits one or more signals simulating a resolver
peak-to-peak voltage amplitude. The voltage of the simulated signals may
initially be within the range of voltages simulating a properly functioning
resolver. The voltage may then be decreased (either instantaneously or
gradually) to simulate a peak-to-peak voltage less than a minimum threshold
voltage to determine if motor controller transmits an error message in response
to the simulated voltage being less than the minimum threshold voltage. If
motor controller 120 transmits an error message in response to the simulated
voltage being less than the minimum threshold voltage, resolver decoder 1250
or 1275 is not experiencing a malfunction associated with detecting a loss of
signal fault condition. Alternatively, if motor controller 120 fails to transmit

17
an error message in response to the simulated voltage being less than the
minimum threshold voltage, resolver decoder 1250 or 1275 is experiencing a
malfunction associated with detecting a loss of signal fault condition.
[0057] In determining if the malfunction resolver decoder 1250 or 1275 is
experiencing is associated with detection of a DC bias OOR fault condition,
resolver simulator 300 transmits one or more signals simulating a resolver DC
bias. The DC bias of the simulated signals may initially be within a range of
DC biases simulating a properly functioning resolver. The DC bias may then
be increased (either instantaneously or gradually) and/or decreased (either
instantaneously or gradually) to simulate a DC bias that is either greater than a
maximum threshold DC bias or a DC bias that is below a minimum threshold
DC bias to determine if motor controller transmits an error message in
response thereto. If motor controller 120 transmits an error message in
response to the simulated DC bias being greater than the maximum threshold
DC bias and/or (depending upon whether testing one of or both of the
maximum and minimum DC bias threshold(s)) being less than the minimum
threshold DC bias, resolver decoder 1250 or 1275 is not experiencing a
malfunction associated with detecting a DC bias OOR fault condition.
Alternatively, if motor controller 120 fails to transmit an error message in
response to the simulated DC bias being greater than the maximum threshold
DC bias and/or (depending upon whether testing one of or both of the
maximum and minimum DC bias threshold(s)) being less than the minimum
threshold DC bias, resolver decoder 1250 or 1275 is experiencing a
malfunction associated with detecting a DC bias OOR fault condition.
[0058] After the type of malfunction is determined, the magnitude of the
malfunction can be quantified (step 455). The magnitude of the malfunction
may be quantified by determining a threshold motor speed (for a loss of
tracking fault condition), a threshold peak-to-peak voltage (for a loss of signal

18
fault condition or a degraded signal condition), or a DC bias threshold (for a
DC bias OOR fault condition).
[0059] The threshold motor speed is the motor speed at which motor
controller 120 transmits the error message in response to signals from resolver
simulator 300. To determine the threshold motor speed when a loss of
tracking fault condition exists, waveform generator 310 (see FIG. 3) may be
adjusted (either gradually or instantaneously) so that resolver simulator 300
outputs signals simulating varying motor speeds until motor controller 120
transmits the error signal. The simulated motor speed may be started at a
speed representing a properly functioning resolver signal or a speed
representing the loss of tracking fault condition. The threshold motor speed
may then be compared to the motor speed at which motor controller 120
should transmit the error message to quantify the loss of tracking fault
condition.
[0060] The threshold peak-to-peak voltage is the voltage at which at which
motor controller 120 transmits the error message in response to signals from
resolver simulator 300. In determining the threshold peak-to-peak voltage
when a degraded signal fault condition exists, gain circuit 350 (see FIG. 3)
may be adjusted (either gradually or instantaneously) so that resolver
simulator 300 outputs signals simulating varying peak-to-peak voltages until
motor controller 120 transmits the error signal. The simulated peak-to-peak
voltages may be started at a voltage representing a properly functioning
resolver signal or a voltage representing the degraded signal fault condition.
The threshold voltage may then be compared to the voltage at which motor
controller 120 should transmit the error message to quantify the degraded
signal fault condition. Similarly, gain circuit 350 may be adjusted (either
gradually or instantaneously) so that resolver simulator 300 outputs signals
simulating varying peak-to-peak voltages to determine the threshold peak-to-
peak voltage when a loss of signal fault condition exists.

19
[0061] The threshold DC bias is the DC bias at which at which motor
controller 120 transmits the error message in response to signals from resolver
simulator 300. In determining the threshold DC bias when a DC bias OOR
fault condition exists, DC offset circuit 3235 and/or DC offset circuit 3335
(see FIG. 3) may be adjusted (either gradually or instantaneously) so that
resolver simulator 300 outputs signals simulating varying DC biases until
motor controller 120 transmits the error signal. The simulated DC biases may
be started at a DC bias representing a properly functioning resolver signal or a
DC bias representing the short circuit fault condition. The threshold DC bias
may then be compared to the DC bias at which motor controller 120 should
transmit the error message to quantify the short circuit fault condition.
[0062] Sometimes when a malfunction exists in system 10, which of motor-
resolver systems 100 and 150 has the problem is known. However, whether
the malfunction is on the motor side or the motor controller side is unknown.
For example, if a malfunction exists in system 10, it may be known that the
malfunction is within motor-resolver system 100, however; whether resolver
105 or resolver decoder 1250 is the malfunctioning component is unknown.
In another example, if a malfunction exists in system 10, it may be known that
the malfunction is within motor-resolver system 150, however; whether
resolver 155 or resolver decoder 1275 is the malfunctioning component is
unknown.
[0063] FIG. 5 is a flow diagram representing one exemplary embodiment of
a method 500 for diagnosing faults in system 10 when it is known that the
malfunction is in motor-resolver system 100 or motor-resolver system 150.
Method 500 begins by coupling a resolver (e.g., resolver 105) to a resolver
decoder (e.g., resolver decoder 1275) (step 505), and coupling another resolver
(e.g., resolver 155) to another resolver decoder (e.g., resolver decoder 1250)
(step 510). A signal is transmitted from resolver 105 to resolver decoder 1275
(step 515) to determine if the motor controller (e.g., motor controller 120)

20
transmits an error message (step 520). A signal is also transmitted from
resolver 155 to resolver decoder 1250 (step 525) to determine motor controller
120 transmits an error message (step 530).
[0064] Once steps 505 through 525 have been performed, which motor
controller or resolver decoder is malfunctioning can be determined (step 535).
If the error message transmitted by motor controller 120 "jumps" from one
resolver decoder to the other resolver decoder, the motor is malfunctioning. If
the error message fails to jump from one resolver decoder to the other resolver
decoder (i.e., stays at the same resolver decoder), the resolver decoder is
malfunctioning. For example, if it is known that motor-resolver system 100 is
malfunctioning, after resolver 105 transmits a signal to resolver decoder 1275
and resolver 155 transmits a signal to resolver decoder 1250, if controller 120
transmits the error message from resolver decoder 1275, resolver 105 is
malfunctioning. If controller 120 transmits the error message from resolver
decoder 1250, resolver decoder 1250 is malfunctioning. In an example when
it is known that motor-resolver system 150 is malfunctioning, if controller 120
transmits the error message from resolver decoder 1250, resolver 155 is
malfunctioning; but if controller 120 transmits the error message from resolver
decoder 1275, resolver decoder 1275 is malfunctioning.
[0065] When resolver decoder 1250 or 1275 is malfunctioning, which of the
multiple fault conditions resolver decoder 1250 or 1275 is experiencing can be
determined in a manner similar to step 450 discussed above with respect to
FIG. 4 (step 540). Furthermore, once the type of fault condition is determined,
the magnitude of the fault condition(s) can be determined in a manner similar
to step 455 discussed above with respect to FIG. 4 (step 545).

21
[0066] FIG. 6 is a flow diagram representing one exemplary embodiment of
a method 600 for diagnosing faults in system 10. Method 600 begins by
knowing that a motor controller (e.g., motor controller 120) indicates that side
A (e.g., motor-resolver system 100 in FIG. 1) and side B (e.g., motor-resolver
system 150 in FIG. 1) of system 10 are malfunctioning (i.e., are "bad") (step
605).
[0067] Method 600 also includes connecting system 10 to device 200 and
swapping (via swapping circuits 220 and 240) the coupling of sides A and B
(step 610). That is, for example, coupling resolver 105 to decoder resolver
1275 and coupling resolver 155 to resolver decoder 1250 when resolver 105
was initially coupled to resolver decoder 1250 and resolver 155 was initially
coupled to resolver decoder 1275.
[0068] Side A is checked to determine if it is functioning properly (i.e., if it
is "good") and side B is checked to determine if it is malfunctioning or bad
(step 615). If side A is functioning properly and side B is malfunctioning,
decoder A (e.g., resolver decoder 1250) and resolver B (e.g., resolver 155) are
determined to be functioning properly (i.e., are "good") (step 620), and
decoder B (e.g., resolver decoder 1275) and resolver A (e.g., resolver 105) are
determined to be malfunctioning (i.e., are "bad") (step 625).
[0069] Side A is checked to determine if it is malfunctioning and side B is
checked to determine if it is functioning properly (step 630). If side A is
malfunctioning and side B is functioning properly, decoder B (e.g., resolver
decoder 1275) and resolver A (e.g., resolver 105) are determined to be
functioning properly (i.e., are "good") (step 635), and decoder A (e.g., resolver
decoder 1250) and resolver B (e.g., resolver 155) are determined to be
malfunctioning (i.e., are "bad") (step 640).
[0070] If the answer to both steps 615 and 630 are NO, it is determined that
resolvers A and B, or decoders A and B are both malfunctioning (step 645).
In this situation, a resolver simulator (e.g., resolver simulator 300) is used to

22
check decoders A and B (step 650) to determine if decoders A and B are both
functioning properly (step 655). If decoders A and B are functioning properly,
resolvers A and B are both malfunctioning (step 660); otherwise, decoders A
and B are both malfunctioning (step 665).
[0071] While at least one exemplary embodiment has been presented in the
foregoing detailed description of the invention, it should be appreciated that a
vast number of variations exist and that the method steps described with
reference to FIGS. 4 and 5 may be performed in any order and/or one or more
steps may be omitted. It should also be appreciated that the exemplary
embodiment or exemplary embodiments are only examples, and are not
intended to limit the scope, applicability, or configuration of the invention in
any way. Rather, the foregoing detailed description will provide those skilled
in the art with a convenient road map for implementing an exemplary
embodiment of the invention, it being understood that various changes may be
made in the function and arrangement of elements described in an exemplary
embodiment without departing from the scope of the invention as set forth in
the appended claims and their legal equivalents.

23
CLAIMS
We claim:
1. A system for diagnosing faults in multiple, associated motor-resolver
systems including a first resolver, a second resolver, and a motor controller
including a first decoder and a second decoder, the system comprising:
5 a first swapping circuit selectively coupling the first resolver to one
of the first decoder and the second decoder; and
a second swapping circuit selectively coupling the second resolver to
one of the first decoder and the second decoder.
2. The system of claim 1, further comprising:
an adjustable resolver simulator configured to generate outputs
simulating at least one resolver fault condition of a plurality of resolver fault
conditions; and
5 a third swapping circuit selectively coupling one of the resolver
simulator and the first resolver to the first swapping circuit.
3. The system of claim 2, further comprising a fourth swapping circuit
selectively coupling one of the resolver simulator and the second resolver to the
second swapping circuit.
4. The system of claim 1, further comprising:
an adjustable resolver simulator configured to generate outputs
simulating at least one resolver fault condition of a plurality of resolver fault
conditions; and
5 a third swapping circuit selectively coupling one of the resolver
simulator and the second resolver to the second swapping circuit.

24
5. A method for diagnosing faults in multiple, associated motor-resolver
systems including (i) a first motor rcsolver that transmits a first resolver signal to a
first decoder and (ii) a second motor resolver that transmits a second resolver signal
to a second decoder, wherein the first and second decoders are each configured to
5 detect fault conditions represented in the first and second resolver signals,
respectively, and configured to generate a first and second fault signal, respectively,
in response to detecting a fault condition, and wherein the first fault signal has been
generated, the method comprising the steps of:
applying the second signal to the first decoder to determine that the first
10 decoder is malfunctioning if the first decoder continues to generate the first fault
signal; and
applying the first signal to the second decoder to determine that the first
motor is malfunctioning if the second decoder generates the second fault signal.
6. The method of claim 5, wherein the first decoder includes a
malfunction, the method further comprising the step of determining a type of the
fault condition causing the malfunction.
7. The method of claim 6, further comprising the step of quantifying a
threshold of the fault condition.
8. The method of claim 7, wherein the quantifying step comprises the
steps of:
transmitting a plurality of signals simulating varying rates of speeds
to the first decoder; and
5 identifying a rate of speed that causes the motor controller to transmit
the first fault signal in response to the plurality of signals.

25
9. The method of claim 7, wherein the quantifying step comprises the
steps of:
transmitting a plurality of signals simulating varying DC biases; and
identifying a DC bias that causes the motor controller to transmit the
5 first fault signal in response to the plurality of signals.
10. The method of claim 7, wherein the quantifying step comprises the
steps of:
transmitting a plurality of signals simulating varying peak-to-peak
voltage amplitudes greater than a maximum threshold voltage; and
5 identifying a voltage that causes the motor controller to transmit the
error message in response to the plurality of signals.
11. The method of claim 7, wherein the quantifying step comprises the
steps of:
transmitting a plurality of signals simulating varying peak-to-peak
voltage amplitudes less than a minimum threshold voltage; and
5 identifying a voltage that causes the motor controller to transmit the
error message in response to the plurality of signals.
12. A method for diagnosing faults in multiple, associated motor-resolver
systems including a first motor having an associated first resolver, a second motor
having an associated second resolver, and a motor controller having a first decoder
and a second decoder, the method comprising the steps of:
5 transmitting a first signal from the first resolver to the first decoder;
transmitting a second signal from the second resolver to the second
decoder;
transmitting a third signal from the first resolver to the second
decoder;

26
10 transmitting a fourth signal from the second resolver to the first decoder;
and
determining if one of the first decoder, the second decoder, the first
motor, and the second motor is malfunctioning.
13. The method of claim 12, wherein the determining step comprises the
steps of:
determining if the motor controller transmits an error message in
response to one of the first signal and the second signal; and
5 determining if the motor controller transmits the error message in
response to one of the third signal and the fourth signal.
14. The method of claim 13, the method further comprising the steps of:
determining that the first motor is malfunctioning if the motor
controller transmits the error message in response to both the first signal and the
third signal;
5 determining that the second motor is malfunctioning if the motor
controller transmits the error message in response to both the second signal and the
fourth signal.
15. The method of claim 13, further comprising the steps of:
determining that the first decoder is malfunctioning if the motor
controller transmits the error message in response to both the first signal and the
fourth signal; and
5 determining that the second decoder is malfunctioning if the motor
controller transmits the error message in response to both the second signal and the
third signal.

27
16. The method of claim 15, wherein one of the first decoder and the
second decoder includes a malfunction, the method further comprising the step of
determining a type of fault condition causing the malfunction from a group of fault
conditions comprised of a loss of tracking fault condition, a loss of signal fault
5 condition, a short circuit fault condition, and a degraded signal fault condition.
17. The method of claim 16, further comprising the step of quantifying a
threshold of the one of the loss of tracking fault condition, the loss of signal fault
condition, the degraded signal fault condition, and the short circuit fault condition.
18. The method of claim 17, wherein the quantifying step comprises the
steps of:
transmitting a plurality of signals simulating varying rates of speeds
to the first decoder; and
5 identifying a rate of speed that causes the motor controller to transmit
the error message in response to the plurality of signals.
19. The method of claim 17, wherein the quantifying step comprises the
steps of:
transmitting a plurality of signals simulating varying DC biases; and
identifying a DC bias that causes the motor controller to transmit the
5 error message in response to the plurality of signals.

28
20. The method of claim 17, wherein the quantifying step comprises the
steps of:
transmitting a plurality of signals simulating varying peak-to-peak
voltage amplitudes one of greater than a maximum threshold voltage and less than a
5 minimum threshold voltage; and
identifying a voltage that causes the motor controller to transmit the
error message in response to the plurality of signals.

Apparatus and methods are provided for diagnosing faults in multiple, associated
motor-resolver systems. One apparatus includes a swapping circuit coupling a first resolver to
a first or second decoder, and a swapping circuit coupling a second resolver to the first or second decoder. One method includes applying a signal from a resolver to a first decoder to
determine that the first decoder is lfunctioning if the first decoder continues to generate a
fault signal, and applying a signal from a different resolver to a second decoder to determine that a motor associated with the first decoder is malfunctioning if the second decoder generates a fault signal. Another method includes transmitting a signal from a resolver to first and second decoders, transmitting a signal from a different resolver to the first and second decoders, and determining if the first decoder, second decoder, a first motor, or a second motor is malfunctioning.

Documents:

00459-kol-2008-abstract.pdf

00459-kol-2008-claims.pdf

00459-kol-2008-correspondence others.pdf

00459-kol-2008-description complete.pdf

00459-kol-2008-drawings.pdf

00459-kol-2008-form 1.pdf

00459-kol-2008-form 2.pdf

00459-kol-2008-form 3.pdf

00459-kol-2008-form 5.pdf

459-KOL-2008-(01-11-2012)-ABSTRACT.pdf

459-KOL-2008-(01-11-2012)-ANNEXURE TO FORM 3.tif

459-KOL-2008-(01-11-2012)-CLAIMS.pdf

459-KOL-2008-(01-11-2012)-DESCRIPTION (COMPLETE).pdf

459-KOL-2008-(01-11-2012)-DRAWINGS.pdf

459-KOL-2008-(01-11-2012)-EXAMINATION REPORT REPLY RECEIVED.pdf

459-KOL-2008-(01-11-2012)-FORM-1.pdf

459-KOL-2008-(01-11-2012)-FORM-2.pdf

459-KOL-2008-(01-11-2012)-OTHERS.pdf

459-KOL-2008-(01-11-2012)-PA.pdf

459-KOL-2008-(01-11-2012)-PETITION UNDER RULE 137.pdf

459-KOL-2008-ASSIGNMENT.pdf

459-KOL-2008-CORRESPONDENCE OTHERS 1.1.pdf

459-KOL-2008-CORRESPONDENCE OTHERS 1.2.pdf

459-kol-2008-form 18.pdf

459-KOL-2008-PRIORITY DOCUMENT.pdf

« Previous Patent

Next Patent »

Patent Number

259930

Indian Patent Application Number

459/KOL/2008

PG Journal Number

14/2014

Publication Date

04-Apr-2014

Grant Date

29-Mar-2014

Date of Filing

06-Mar-2008

Name of Patentee

GM GLOBAL TECHNOLOGY OPERATIONS, INC.

Applicant Address

300 GM RENAISSANCE CENTER DETROIT, MICHIGAN

Inventors:

#	Inventor's Name	Inventor's Address
1	DAVID T. FU	5817 STONEHAVEN BLVD ROCHESTER, MICHIGAN 48034
2	WEI D. WANG	1526 CHARLEVOIS TROY, MICHIGAN 48085

PCT International Classification Number

B60T13/26; B60T13/24

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	11/748,054	2007-05-14	U.S.A.