Title of Invention

APPARATUS AND SYSTEMS FOR COMMON MODE VOLTAGE-BASED AC FAULT DETECTION, VERIFICATION AND/OR IDENTIFICATION

Abstract Apparatus for AC fault (ACF) detection are provided. In addition, apparatus for AC fault (ACF) detection and verification are provided. In addition, apparatus for identification of a module which is the cause of an AC fault (ACF) are provided. In one implementation, one or more of these apparatus can be combined to provide a fast, simple, low cost and reliable ACF detection, verification and/or identification circuit.
Full Text APPARATUS AND SYSTEMS FOR COMMON MODE VOLTAGE-
BASED AC FAULT DETECTION, VERIFICATION AND/OR
IDENTIFICATION
TECHNICAL FIELD
[0001] The present invention generally relates to protection of electric and
hybrid vehicle power systems, and more particularly relates to detecting an
alternating current fault (ACF), and/or verifying an ACF and/or identifying a
source of an ACF.
BACKGROUND OF THE INVENTION
[0002] Electric and hybrid vehicles typically include an alternating current
(AC) electric motor which is driven by a direct current (DC) power source,
such as a storage battery. Motor windings of the AC electric motor can be
coupled to inverter module(s) which perform a rapid switching function to
convert the DC power to AC power which drives the AC electric motor.
[0003] Many electric and hybrid vehicles implement an isolated high
voltage DC bus which couples the inverter module(s) to the DC power source.
Other modules, such as devices, components or circuits, can also be coupled to
the high voltage DC bus. In some situations one of more of these modules can
operate improperly and cause an electrical AC fault (ACF) to occur along the
high voltage DC bus which causes high voltage spikes that can potentially
damage other modules coupled to the high voltage DC bus.
[0004] One way to address ACFs is to implement a Ground Fault
Interrupter (GFI) (sometimes also referred to as a residual current device
(RCD), residual current circuit breaker (RCCB), ground fault circuit
interrupter (GFCI)), that observes the respective currents at a ground terminal
and a supply terminal, and disconnects a circuit coupled between these

terminals when the differential current flow between these terminals is not
balanced (i.e., zero (0)) since this signifies current leakage. Such ground fault
detection circuits typically implement current transformers to detect ACF
currents in the ground path. However, transformer-based ground fault
detectors are expensive and bulky.
[0005] Another way to address ACFs is to implement ground fault
detection using software algorithms. However, such software algorithms have
long detection times.
[0006] Accordingly, it is desirable to provide a fast, simple, low cost and
reliable ACF detection and/or verification circuit. It would also be desirable
to provide a fast, simple, low cost and reliable ACF identification circuit
which can aid in diagnosing the source of an ACF so that the source of the
ACF can be turned off or disconnected from the high voltage DC bus when an
ACF occurs. Furthermore, other desirable features and characteristics of the
present invention will become apparent from the subsequent detailed
description and the appended claims, taken in conjunction with the
accompanying drawings and the foregoing technical field and background.
SUMMARY OF THE INVENTION
[0007] Embodiments of the present invention relate to apparatus for AC
fault (ACF) detection, apparatus for AC fault (ACF) detection and
verification, and apparatus for identification of a module which is the cause of
an AC fault (ACF). In one embodiment, one or more of these apparatus can
be combined to provide a fast, simple, low cost and reliable ACF detection,
verification and/or identification circuit.
[0008] In one embodiment, a hybrid/electric power train system is
provided that includes a bus, one or more modules coupled to the bus, and a
circuit designed to detect an AC fault (ACF) caused by one of the modules.
Each module has a fundamental operating frequency (fCM)associated
therewith. The circuit comprises a common mode voltage detector circuit

designed to generate a common mode AC voltage signal (VCM) by removing a
differential mode voltage component from a DC input signal from the bus.
The circuit comprises a magnitude detector coupled to the common mode
voltage detector circuit and designed to determine whether a measured
magnitude of the common mode AC voltage signal (VCM) is greater than or
equal to a threshold voltage (VTH). The magnitude detector also generates an
AC fault (ACF) detection signal when the measured magnitude of the
common mode AC voltage signal (VCM) is greater than or equal to the
threshold voltage (VTH)-
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. 1A illustrates a simplified block diagram of a power
distribution system architecture implemented in a hybrid/electric vehicle
(HEV) according to one exemplary implementation of the present invention;
[0011] FIG. IB illustrates the high voltage (HV) DC input signal from a
HV bus relative to chassis ground;
[0012] FIG. 2A illustrates a simplified block diagram of a fault detection
circuit (FDC) according to one exemplary implementation of the present
invention;
[0013] FIG. 2B is a graph which illustrates a measured level of the voltage
on +HV bus relative to chassis ground;
[0014] FIG. 2C is a graph which illustrates a common mode AC voltage
signal (VCM) during a normal operation and when an ACF event occurs;
[0015] FIG. 2D illustrates a simplified block diagram of a fault detection
and verification circuit (FDVC) according to one exemplary implementation
of the present invention;

[0016] FIG. 2E illustrates a simplified block diagram of a fault detection,
verification and identification circuit (FDVIC) according to one exemplary
implementation of the present invention;
[0017] FIG. 3A and 3B illustrate a method for detecting, verifying and/or
identifying an AC fault (ACF) according to one exemplary implementation of
the present invention; and
[0018] FIG. 4 illustrates another method for detecting, verifying and/or
identifying an AC fault (ACF) according to another exemplary
implementation of the present invention.
DESCRIPTION OF AN EXEMPLARY EMBODIMENT
[0019] As used herein, the word "exemplary" means "serving as an
example, instance, or illustration." The following detailed description is
merely exemplary in nature and is not intended to limit the invention or the
application and uses of the invention. Any embodiment described herein as
"exemplary" is not necessarily to be construed as preferred or advantageous
over other embodiments. All of the embodiments described in this Detailed
Description are exemplary embodiments provided to enable persons skilled in
the art to make or use the invention and not to limit the scope of the invention
which is defined by the claims. Furthermore, there is no intention to be bound
by any expressed or implied theory presented in the preceding technical field,
background, brief summary or the following detailed description.
[0020] Before describing in detail embodiments that are in accordance
with the present invention, it should be observed that the embodiments reside
primarily in combinations of method steps and apparatus components related
to AC fault (ACF) detection, verification and/or identification. It will be
appreciated that embodiments of the invention described herein can be
implemented using hardware, software or a combination thereof. The AC
fault (ACF) detection, verification and/or identification circuits described
herein may comprise various components, modules, circuits and other logic

which can be implemented using a combination of analog and/or digital
circuits, discrete or integrated analog or digital electronic circuits or
combinations thereof. In some implementations, the ACF detection,
verification and/or identification circuits described herein can be implemented
using one or more application specific integrated circuits (ASICs), one or
more microprocessors, and/or one or more digital signal processor (DSP)
based circuits when implementing part or all of the ACF detection, verification
and/or identification logic in such circuits. It will be appreciated that
embodiments of the invention described herein may be comprised of one or
more conventional processors and unique stored program instructions that
control the one or more processors to implement, in conjunction with certain
non-processor circuits, some, most, or all of the functions for AC fault (ACF)
detection, verification and/or identification, as described herein. As such, these
functions may be interpreted as steps of a method for AC fault (ACF)
detection, verification and/or identification. Alternatively, some or all
functions could be implemented by a state machine that has no stored program
instructions, or in one or more application specific integrated circuits (ASICs),
in which each function or some combinations of certain of the functions are
implemented as custom logic. Of course, a combination of the two approaches
could be used. Thus, methods and means for these functions have been
described herein. Further, it is expected that one of ordinary skill,
notwithstanding possibly significant effort and many design choices motivated
by, for example, available time, current technology, and economic
considerations, when guided by the concepts and principles disclosed herein
will be readily capable of generating such software instructions and programs
and ICs with minimal experimentation.
[0021] Overview
[0022] Embodiments of the present invention relate to methods and
apparatus for AC fault (ACF) detection, methods and apparatus for AC fault
(ACF) detection and verification, and methods and apparatus for identification
of a module which is the cause of an AC fault (ACF). In one embodiment,

one or more of these methods and apparatus can be combined to provide a
fast, simple, low cost and reliable ACF detection, verification and/or
identification circuit.
[0023] The disclosed methods and apparatus can be implemented in
operating environments where ACFs are caused by or as a result of modules
implemented along a high-voltage bus in hybrid/electric vehicle (HEV). In the
exemplary implementations which will now be described, the fault detection,
verification and/or identification techniques and technologies will be described
as applied to a hybrid/electric vehicle (HEV). However, it will be appreciated
by those skilled in the art that the same or similar fault detection, verification
and/or identification techniques and technologies can be applied in the context
of other AC systems which are susceptible to damage caused by an AC fault
(ACF) event. In this regard, any of the concepts disclosed here can be applied
generally to "vehicles," and as used herein, the term "vehicle" broadly refers
to a non-living transport mechanism having an AC motor or device that can
cause an AC fault to ground (chassis) potential. Examples of such vehicles
include automobiles such as buses, cars, trucks, sport utility vehicles, vans,
vehicles that do not travel on land such as mechanical water vehicles including
watercraft, hovercraft, sailcraft, boats and ships, mechanical under water
vehicles including submarines, mechanical air vehicles including aircraft and
spacecraft, mechanical rail vehicles such as trains, trams and trolleys, etc. In
addition, the term "vehicle" is not limited by any specific propulsion
technology such as gasoline or diesel fuel. Rather, vehicles also include
hybrid vehicles, battery electric vehicles, hydrogen vehicles, and vehicles
which operate using various other alternative fuels.
[0024] Exemplary Implementations
[0025] FIG. 1A illustrates a simplified block diagram of a power
distribution system architecture 10 implemented in a hybrid/electric vehicle
(HEV) according to one exemplary implementation of the present invention.
[0026] The system 10 comprises a DC power source 20 (e.g., a battery or
batteries), an inverter module 30, a high voltage DC bus 40 having two DC

bus terminals (+HV, -HV) 42, 44, an AC motor 50, a number of
modules/devices/circuits 60-80 coupled to the high voltage DC bus 40, a fault
detection, verification and/or identification (FDVI) circuit or module 100
designed to detect and verify an AC fault (ACF) and to identify a particular
one of the modules/devices/circuits 30, 60-80 which is the source or cause of
the ACF, a processor 92, a display 94 and a speaker 96.
[0027] The high-voltage bus 40 is a conductor used to couple the DC
power source 20, inverter module 30 and modules 60-80. The high-voltage
bus 40 can be made of a conductive material, such as copper or aluminum. In
these implementations, the high-voltage DC bus 40 is isolated from the vehicle
chassis or "ground."
[0028] The AC motor 50 can be a 'wound motor" with a stator wound into
definite poles.
[0029] The inverter module 30 is coupled to the AC motor 50 using
another bus. The inverter module 30 is a circuit or other device which
converts direct current (DC) power to alternating current (AC) power, usually
with an increase in voltage. Among other things, an inverter module
oftentimes includes a DC input filter know as an electromagnetic interference
(EMI) filter 32 which includes expensive filter capacitors (referred to as "Y
capacitors") connected between chassis (ground) and the high voltage DC bus
40. In this implementation, the two DC bus terminals +HV 42,-HV 44 are
referenced to ground (e.g., the vehicle chassis), and two Y-capacitors (not
illustrated) are coupled together (at ground) between the two terminals +HV
42,-HV 44. The DC high voltage bus 40, 42 is isolated from chassis ground
with a DC resistance usually greater than 1.0 megaohm. The voltage on the
DC bus can range anywhere from +/- 50 V DC to +/- several hundred volts
DC. Usually the DC high voltage bus is referenced at 1/2 the amplitude
relative to chassis ground. For example, terminals of the a 100 V DC bus can
be biased at +50 V relative to chassis ground and - 50 V relative to chassis
ground. The two DC bus terminals +HV 42,-HV 44 are coupled to the
inverter 30. Such capacitors are not only expensive, but are relatively difficult

to replace in the event they fail. An ACF event may cause a high-AC current
to be applied to the two Y-capacitors in excess of 100 times the normal
operating current, to which the two Y-capacitors will fail.
[0030] As used herein the term "module" refers to a device, a circuit, an
electrical component, and/or a software based component for performing a
task. The modules/devices/circuits 30, 60-80 each have an identifiable,
fundamental operating switching frequency (fCM) associated therewith, that
switches power from the DC bus. Although only four
modules/devices/circuits 30, 60-80 are illustrated for purposes of discussion, it
will be appreciated that in other implementations fewer or more
modules/devices/circuits 60-80 can be coupled to the terminals (+HV 42,-HV
44) of the high-voltage bus 40. The modules/devices/circuits 60-80 can be, for
example, a converter (e.g., a DC-to-DC converter module), an inverter (e.g., a
Power Inverter Module (PIM) such as a quad-PIM) or modules and/or sub-
modules thereof which have an identifiable switching frequency (fCM), an
engine cooling fan module, etc. Each of the modules/devices/circuits 60-80
has a fundamental operating frequency (fCM) associated therewith, and can act
as a source or cause of an ACF along the high voltage DC bus 40. As used
herein, the term "AC fault (ACF)" refers to the switched (AC) output of an
inverter which inadvertently becomes partially or totally shorted to ground
(chassis). An ACF is typically observed or detected by a series of ACF events
or a particular number of consecutive ACF-type voltage spikes.
[0031] FIG. IB illustrates the high voltage DC input signal 115 from the
bus. The high voltage DC input signal 115 includes a common mode noise on
a high-voltage (HV) bus relative to chassis ground. As illustrated in FIG. IB,
the high voltage DC input signal 115 has two components one on the +HV bus
42 relative to chassis ground and another on the -HV bus 44 relative to chassis
ground, and the common mode voltage has the same amplitude and phase
relative to chassis ground. When amplitude of the ripple portion of the high
voltage DC input signal 115 becomes high enough (e.g., when there is a direct

short AC fault (ACF) event), components, such as the Y-capacitors can be
damaged.
[0032] As will be described in detail below, the FDVI module 100 can
detect an ACF event or event(s), and/or verify that ACF event(s) signal an
actual ACF, and/or identify one of the modules which is the cause or source of
a detected ACF or verified ACF. While FIG. 1A illustrates the FDVI module
100 as an independent module that is implemented outside of the inverter
module 30 and the modules 60-70, in other implementations, the FDVI
module 100 can be implemented within or as part of the inverter module 30,
or within or as part of one or more of the modules 60-70.
[0033] FIG. 2A illustrates a simplified block diagram of a fault detection
circuit (FDC) 102 according to one exemplary implementation of the present
invention. The FDC 102 will be described below with reference to an
implementation where the FDC 100 is utilized in a battery or fuel-cell
operated HEV which includes a hybrid/electric power train system 10 such as
that illustrated in FIG. 1A, however, the FDC 102 can be implemented in a
variety of other applications or implementations to detect an ACF. In this
exemplary implementation, the FDC 102 is coupled to the high voltage DC
bus 40 by a high voltage DC input circuit which generates a high-voltage DC
input signal 115 between the DC bus terminals 42, 44.
[0034] The FDC 102 comprises a common mode voltage detector circuit
120 and a level/amplitude/magnitude detector 140. The common mode
voltage detector/measurement circuit 120 designed to receive the high-voltage
DC input signal 115, and to generate a scaled, common mode AC voltage
signal (VCM) 125 by removing a differential mode DC voltage component
from the high-voltage DC input signal 115. The scaled common mode AC
voltage signal (VCM) 125 indicates a scaled value of the common mode AC
voltage measured across the high voltage DC bus 40. For example, as
illustrated in FIG. 2C, when the high-voltage DC input signal 115 passes
through the common mode voltage detector circuit 120, the differential mode
DC component is eliminated and the resultant scaled, common mode AC

voltage signal (VCM) 125 is biased at approximately zero volts (and, in this
example ranges 123 between 13.6 volts and -13.6 volts)
[0035] The level/amplitude/magnitude detector 140 is coupled to the
common mode voltage detector circuit 120. The level/amplitude/magnitude
detector 140 is designed to measure a level of the scaled, common mode AC
voltage signal (VCM) 125, and compare the measured magnitude/amplitude of
the scaled, common mode AC voltage signal (VCM) 125 to a fault detection
threshold voltage (VTH).
[0036] FIG. 2B is a graph which illustrates a measured level of the voltage
on +HV bus 42 relative to chassis ground. Reference numeral 122 illustrates
the voltage waveform during a normal operation of the HV DC bus 40,
whereas reference numeral 124 illustrates the voltage waveform when an ACF
event is occurring on the HV DC bus 40.
[0037] FIG. 2C is a graph which illustrates a measured level of the
common mode AC voltage signal (VCM) 125 when the differential mode
voltage is removed. In this particular example, during normal operation of
the HV DC bus 40, the scaled, common mode AC voltage signal (VCM) 127 is
DC offset at approximately 0.0 volts DC (i.e., the normal ripple voltage 127 is
5 volts peak-to-peak (5VPP) (between arrows 126) and biased at 0.0 volts. By
contrast, during an exemplary ACF event 128 when ACF voltages are present,
the common mode AC voltage signal (VCM) 125 is approximately 27.6 volts
peak-to-peak (Vpp) (between arrows 123) and centered at 0.0 volts.
[0038] Thus, when the measured magnitude/amplitude of the scaled,
common mode AC voltage signal (VCM) 125 is greater than or equal to the
fault detection threshold voltage (VTH) (e.g., when the
level/amplitude/magnitude of the scaled, common mode AC voltage signal
(VCM) 125 crosses the fault detection threshold voltage (VTH)), the
level/amplitude/magnitude detector 140 generates and outputs a signal 145
(e.g., a logical one) which indicates that a ACF event has been detected. By
contrast, when the level/amplitude/magnitude detector 140 determines that the
magnitude/amplitude of the scaled, common mode AC voltage signal (VCM)

125 is less than the fault detection threshold voltage (VTH), the
level/amplitude/magnitude detector 140 does not generate an output and does
not indicate that an ACF event has been detected.
[0039] In some implementations it is desirable to provide fault verification
to help ensure that a perceived ACF event is actually caused by an ACF, and is
not a false indicator due, for instance, to noise or some other intermittent
disturbance in the system.
[0040] FIG. 2D illustrates a simplified block diagram of a fault detection
and verification circuit (FDVC) 104 according to one exemplary
implementation of the present invention. As above, the FDVC 104 will be
described below with reference to an implementation where the FDVC 104 is
utilized in a battery or fuel-cell operated HEV which includes a hybrid/electric
power train system 10 such as that illustrated in FIG. 1 A, however, the FDVC
104 can be implemented in a variety of other applications or implementations
to detect and verify an ACF. As above, in this exemplary implementation, the
FDVC 104 is coupled to the high voltage DC bus 40 by a high voltage DC
input circuit which generates a high-voltage DC input signal 115 between the
DC bus terminals 42, 44.
[0041] The FDVC 104 comprises a common mode voltage detector circuit
120, a level/amplitude/magnitude detector 140, and a fault verification unit
150. The common mode voltage detector circuit 120, and the
level/amplitude/magnitude detector 140 operate as described above with
reference to FIGS. 2A and 2B.
[0042] When the measured magnitude/amplitude of the scaled, common
mode AC voltage signal (VCM) 125 is greater than or equal to the fault
detection threshold voltage (VTH) (e.g., when the level/amplitude/magnitude of
the scaled, common mode AC voltage signal (VCM) 125 crosses the fault
detection threshold voltage (VTH)), the level/amplitude/magnitude detector 140
generates and outputs a counter enable signal 145 (e.g., a logical one) which it
provides to a cycle counter 152 which is implemented in the fault verification
unit 150. By contrast, when the level/amplitude/magnitude detector 140

determines that the magnitude/amplitude of the scaled, common mode AC
voltage signal (VCM) 125 is less than the fault detection threshold voltage
(VTH), the level/amplitude/magnitude detector 140 does not generate an output
(or maintains an output signal (e.g., a logical zero)) which it provides to the
cycle counter 152 in which case the cycle counter 152 is not enabled.
[0043] The cycle counter 152 is enabled by the counter enable signal 145
whenever an ACF event is detected by the level/amplitude/magnitude detector
140 (e.g., signal 145 is high). The cycle counter 152 increments a register (not
illustrated) in the cycle counter 152 if, and only if, the cycle counter 152 is
enabled and an ACF voltage spike is present in the scaled, common mode AC
voltage signal (VCM) 125 while the cycle counter 152 is enabled by the counter
enable signal 145.
[0044] The cycle counter 152 maintains a count which indicates a number
of consecutive periods that the magnitude/amplitude of the scaled, common
mode AC voltage signal (VCM) 125 is greater than or equal to the fault
detection threshold voltage (VTH) while the cycle counter 152 is enabled.
When the count maintained by the cycle counter 152 is greater than or equal a
particular or predetermined threshold number of consecutive cycles (e.g., 3
consecutive times) or "count," then the fault verification unit 150 generates a
fault verification signal 155 to indicate that the ACF has been verified (i.e.,
verifies that the number of ACF voltage spikes is sufficient to signify a true
ACF condition). When the count is greater than or equal to the particular
number, this signifies that the number of consecutive periods during which an
ACF-type pulse or "ACF voltage spike' is received is greater than some
threshold number, and therefore it can be assumed that an actual AC fault
(ACF) exists since this indicates that the scaled, common mode AC voltage
signal (VCM) 125 includes a consecutive string of ACF-type pulses or ACF
voltage spikes rather than an intermittent or random ACF-type pulse or ACF
voltage spike.
[0045] The cycle counter 152 resets whenever the counter enable signal
145 is not received during consecutive periods (as determined from the scaled,

common mode AC voltage signal (VCM) 125). When the cycle counter 152
resets before reaching a particular or predetermined number of consecutive
cycles or "count," then it can be assumed that the ACF-type pulse is an
intermittent or false fault indicator (e.g., in a situation where a single ACF-
type pulse occurs that is not associated with an actual ACF, but is instead
attributable to noise). In this situation, the fault verification unit 150 does not
output a fault verification signal 155.
[0046] In some cases, multiple modules can be provided in a system (as
illustrated for example in FIG. 1A), and each of these modules can act as a
cause or a source of an ACF event. In such cases, it is desirable to provide a
mechanism for identifying the particular module which is the source or cause
of the ACF. In some implementations, once the ACF has been detected and/or
verified, the source of the ACF can be identified so that a control system can
take an appropriate action given the nature of the ACF. In some
embodiments, the methods and apparatus can aid in diagnosing the source of
an ACF so that the source of the ACF can be turned off or disconnected from a
high voltage DC bus.
[0047] FIG. 2E illustrates a simplified block diagram of a fault detection,
verification and identification circuit (FDVIC) 100 according to one
exemplary implementation of the present invention. The FDVIC 100 will be
described below with reference to an implementation where the FDVIC 100 is
utilized in a battery or fuel-cell operated HEV which includes a hybrid/electric
power train system 10 such as that illustrated in FIG. 1A, however, the FDVIC
100 can be implemented in a variety of other applications or implementations
to detect and/or verify an ACF, and/or to identify a module, device or circuit
which is a source of such an ACF. In this exemplary implementation, the
FDVIC 100 is coupled to the high voltage DC bus 40 by a high voltage DC
input circuit which generates a high-voltage DC input signal 115 between the
DC bus terminals 42, 44.
[0048] The FDVIC 100 comprises a common mode voltage detector
circuit 120, a level/amplitude/magnitude detector 140, a fault verification unit

150; a period/frequency detector 160, a module identification unit 170, and a
fault indicator unit 180. The common mode voltage detector circuit 120 and
the level/amplitude/magnitude detector 140 are described above.
[0049] When the measured magnitude/amplitude of the common mode AC
voltage signal (VCM) 125 is greater than or equal to the fault detection
threshold voltage (VTH) (e.g., when the level/amplitude/magnitude of the
common mode AC voltage signal (VCM) 125 crosses the fault detection
threshold voltage (VTH)), the level/amplitude/magnitude detector 140
generates and outputs a counter enable signal 145 (e.g., a logical one) which it
provides to a cycle counter 152 which is implemented in the fault verification
unit 150. The cycle counter 152 indicates that a ACF event has been detected.
[0050] By contrast, when the level/amplitude/magnitude detector 140
determines that the magnitude/amplitude of the common mode AC voltage
signal (VCM) 125 is less than the fault detection threshold voltage (VTH), the
level/amplitude/magnitude detector 140 does not generate an output (or
maintains an output signal (e.g., a logical zero) which it provides) to the cycle
counter 152 in which case the cycle counter 152 is not enabled.
[0051] The fault verification unit 150 is coupled to the
level/amplitude/magnitude detector 140.
[0052] The cycle counter 152 is enabled by the counter enable signal 145
whenever an ACF event is detected by the level/amplitude/magnitude detector
140 (e.g., signal 145 is high). The cycle counter 152 increments a register (not
illustrated) in the cycle counter 152 if, and only if, the cycle counter 152 is
enabled and an ACF voltage spike is present in the common mode AC voltage
signal 125 while the cycle counter 152 is enabled by the counter enable signal
145.
[0053] The cycle counter 152 maintains a count which indicates a number
of consecutive periods that the magnitude/amplitude of the common mode AC
voltage signal 125 is greater than or equal to the fault detection threshold
voltage (VTH) while the cycle counter 152 is enabled. When the count
maintained by the cycle counter 152 is greater than or equal a particular or

predetermined threshold number of consecutive cycles (e.g., 3 consecutive
times) or "count," then the fault verification unit 150 generates a fault
verification signal 155 to indicate that the ACF has been verified (i.e., verifies
that the number of ACF voltage spikes is sufficient to signify a true ACF
condition). When the count is greater than or equal to the particular number,
this signifies that the number of consecutive periods during which an ACF-
type pulse or "ACF voltage spike" is received is greater than some threshold
number, and therefore it can be assumed that an actual AC fault (ACF) exists
since this indicates that the common mode AC voltage signal 125 includes a
consecutive string of ACF-type pulses or ACF voltage spikes rather than an
intermittent or random ACF-type pulse or ACF voltage spike.
[0054] The cycle counter 152 resets whenever the counter enable signal
145 is not received during consecutive periods (as determined from the
common mode AC voltage signal 125). When the cycle counter 152 resets
before reaching a particular or predetermined number of consecutive cycles or
"count," then it can be assumed that the ACF-type pulse is an intermittent or
false fault indicator (e.g., in a situation where a single ACF-type pulse occurs
that is not associated with an actual ACT, but is instead attributable to noise).
In this situation, the fault verification unit 150 does not output a fault
verification signal 155.
[0055] In this implementation, the fundamental frequency (fCM) of the
module causing the ACF can be determined. The frequency detector 160 is
also coupled to the common mode AC voltage signal 125. The frequency
detector 160 is designed to determine a frequency (f) of the common mode AC
voltage signal 125, and to generate a frequency (f) identification signal 165
which indicates the center frequency (fc) of the common mode AC voltage
signal 125.
[0056] The module identification unit 170 is coupled to the frequency
detector 160. The module identification unit 170 is designed to receive the
fundamental operating frequency (ECM) identification signal 165, and
determine the module that is the source of the AC fault (ACF) based on the

fundamental operating frequency (fCM) For example, in one implementation,
the module identification unit 170 can determine the module that is the source
of the AC fault (ACF) by performing a lookup in a lookup table which
associates each module with a corresponding operating frequency of that
module. After determining which module is the source of the AC fault (ACF),
the module identification unit 170 can generate a module identification signal
175 which identifies the module that is the source of the AC fault (ACF).
[0057] The fault indicator unit 180 is coupled to the fault verification unit
150 and the module identification unit 170. When the fault indicator unit 180
receives both the fault verification signal 155 and the module identification
signal 175, the fault indicator unit 180 generates information 185 which
identifies the module which is causing the AC fault (ACF). In one
implementation, the information 185 comprises a fault indicator signal 185.
The fault indicator signal 185 may include, for example, an output fault code
with a corresponding module identifier (ID) which identifies the module
which is causing the AC fault (ACF). In some implementations, the processor
92, upon processing the fault indicator signal 185, can generate a signal which
either stops operation (e.g., turns off) of the module causing the AC fault
(ACF) or disconnects the module causing the AC fault (ACF) from the high
voltage DC bus 40.
[0058] In one implementation, the processor 92, upon processing the fault
indicator signal 185, can send a signal to the display 94 which causes the
display 94 to visually display the module identifier (ID) which identifies the
module which is causing the AC fault (ACF).
[0059] In another implementation, the processor 92, upon processing the
fault indicator signal 185, can send a signal to the an audio unit which includes
speaker 96 thereby causing the speaker 96 to provide an audible indicator
which indicates the AC fault (ACF) and/or identifies the module which is
causing the AC fault (ACF).
[0060] FIG. 3A illustrates a method 200 for detecting, verifying and
identifying an AC fault (ACF) according to one exemplary implementation of

the present invention. The method 200 will be described below with reference
to an implementation where the method 200 is utilized to detect an ACF,
verify an ACF and/or identify a module causing an ACF in a battery or fuel-
cell operated HEV which includes a hybrid/electric powertrain system 10 such
as that illustrated in FIG. 1A; however, the method 200 can be applied in a
variety of other applications or implementations to detect an ACF, verify an
ACF and/or identify a module, device or circuit which is a source or cause of
an ACF.
[0061] At step 205 a counter 205 and/or other calibration parameters are
initialized. At step 210, a high-voltage DC input signal 115 is received, and at
step 220, the differential (DC) voltage component is removed from the high-
voltage DC input signal 115 to generate a scaled, common mode AC voltage
signal (VCM) 125 which indicates a scaled value of a common mode AC
voltage that is measured across the high voltage DC bus 40.
[0062] At step 230, a magnitude of the common mode AC voltage signal
(VCM) 125 is determined at least once during each particular period, and at
step 240, it is determined whether the magnitude of the common mode AC
voltage signal (VCM) 125 is greater than or equal to a fault detection threshold
voltage (VTH)-
[0063] When the magnitude/amplitude of the common mode AC voltage
signal (VCM) 125 is less than the fault detection threshold voltage (VTH), the
method 200 proceeds to step 242 where the cycle counter 152 is reset, and the
method 200 then loops back to step 210. When the magnitude/amplitude of
the common mode AC voltage signal (VCM) 125 is greater than or equal to the
fault detection threshold voltage (VTH), the method 200 proceeds to step 244
where a cycle counter 152 (not illustrated), which counts a number of
consecutive particular periods during which the cycle counter 152 input signal
is received, is incremented.
[0064] Method 200 then proceeds to step 246, where it is determined
whether a count maintained by the cycle counter 152, which indicates a
number of consecutive periods that the magnitude/amplitude of the common

mode AC voltage signal (VCM) 125 is greater than or equal to the fault
detection threshold voltage (VTH), is greater than or equal to is greater than or
equal to a particular threshold number (e.g., 3).
[0065] When it is determined at step 246 that the count maintained by the
cycle counter 152 is less than the particular threshold number (e.g., 3), the
method 200 loops back to step 210, to continue monitoring for additional ACF
voltage spikes. Notably, if another spike is not detected at step 240 before
reaching a particular count, then the counter resets since the number of
consecutive particular periods during which the counter input signal is
received is less than a threshold number, and it can therefore be assumed that
the prior ACF-type pulses were intermittent or false fault indicators.
[0066] When it is determined at step 246 that the count maintained by the
cycle counter 152 is greater than or equal to the particular threshold number
(e.g., 3), the method 200 proceeds to step 248, where a fault verification signal
155 is generated. When the number of consecutive particular periods during
which an ACF-type pulse is received is greater than the particular threshold
number, detection of an ACF is verified by generating a fault verification
signal. In short, it can be assumed that an actual AC fault (ACF) exists (as
opposed to false indicator, for instance, in a situation where a single pulse
occurs that is not associated with an actual ACF), when the count exceeds the
particular threshold number (e.g., 3). Stated differently, if the number of
consecutive particular periods during which the cycle counter 152 input signal
is received is greater than or equal to the threshold number, there is a good
chance that an actual AC fault (ACF) exists since this indicates that the
common mode AC voltage signal 125 includes a continuous number of ACF-
type pulses rather than an intermittent or random ACF-type pulse.
[0067] Steps 250, 260 and 270 are optional (as indicated by dotted-line
boxes) and can be implemented when module identification is performed.
When steps 250 and 260 are performed, at step 250, a frequency (f) of the
common mode AC voltage signal 125 is determined and a frequency (f)
identification signal 165, which indicates the center frequency (fc) of the

common mode AC voltage signal 125. is generated. Then, based on the
frequency (f) identification signal 165, at step 260 the method 200 determines
which module is the source of the AC fault (ACF). For example, in one
implementation, the module that is the source of the AC fault (ACF) can be
determined by using the center frequency (fc) of the common mode AC
voltage signal 125 to perform a lookup in a lookup table which associates each
module with a corresponding operating switching frequency of that module.
[0068] Once the ACF has been verified (step 248) and the module which
is the source or cause of the ACF has been identified (step 260), the method
can proceed to step 270, where information 185 is generated which identifies
the module that is the source or cause of the AC fault (ACF). In one
implementation, the information 185 comprises a fault indicator signal 185
which can include, for example, an output fault code with a corresponding
module identifier (ID) which identifies the module which is causing the AC
fault (ACF).
[0069] Steps 280, 290 and 295 are optional (as indicated by based-line
boxes). The method 200 can optionally perform one or more of steps 280,
290, and 295, and in this regard, each of steps 290 and 295 are optional (as
illustrated in FIG. 3 where step 280 can be performed in combination with
either of steps 290, 295). In other implementations, two or more of steps 280,
290, and 295 can be performed in series and/or in parallel with each other
(e.g., step 280, then step 290; step 280, then step 295; step 280, step 290, then
step 295; step 280, step 290, then step 295; step 290, then step 295 or vice-
versa, etc.).
[0070] When the method 200 proceeds to optional step 280, operation of
the module causing the ACF can be stopped (e.g., turned off or disconnected
from the high voltage DC bus 40). At optional step 290, a module identifier
(ID) which identifies the module which is causing the AC fault (ACF) can be
visually displayed on a user interface. At optional step 295, an audible
indicator cab be generated which indicates the AC fault (ACF) condition
and/or identifies the module which is causing the AC fault (ACF).

[0071] FIG. 4 illustrates a method 300 for detecting, verifying and
identifying an AC fault (ACF) according to another exemplary
implementation of the present invention. As above, method 300 can be
applied in a variety of applications or implementations to detect an ACF,
verify an ACF and/or identify a module, device or circuit which is a source of
an ACF.
[0072] At step 305 a counter and/or other calibration parameters are
initialized. A high-voltage DC input signal 115 is received, and at step 320, a
common mode AC voltage signal (VCM) 125 is measured by removing the
differential (DC) voltage component from the high-voltage DC input signal
115. This results in a scaled, common mode AC voltage signal (VCM) 125
which is scaled to a level suitable for processing by electronic circuits.
[0073] At step 330, a magnitude/amplitude of the common mode AC
voltage signal (VCM) 125 is determined, and at step 340, it is determined
whether the magnitude of the common mode AC voltage signal (VCM) 125 is
greater than or equal to a fault detection threshold voltage (VTH)-
[0074] When the magnitude/amplitude of the common mode AC voltage
signal (VCM) 125 is less than the fault detection threshold voltage (VTH), the
cycle counter 152 resets, and the method 300 loops back to step 320.
[0075] When the magnitude/amplitude of the common mode AC voltage
signal (VCM) 125 is greater than or equal to the fault detection threshold
voltage (VTH), the method 300 proceeds to steps 350-376, where module
identification is performed. At step 350, a common mode frequency (fCM) of
the common mode AC voltage signal (VCM) 125 is determined. At step 362,
364, 366 a series of checks are performed to identify a module which in the
source or cause of the ACF. For example, at step 362, it is determined
whether an absolute value of the difference between the common mode
frequency (fCM) of the common mode AC voltage signal (VCM) 125 and a first
threshold frequency (fTH1) is less than a first frequency differential (Af1). If
the absolute value of the difference between the common mode frequency
(fCM) of the common mode AC voltage signal (VCM) 125 and the first

threshold frequency (fTH1) is less than the first frequency differential (Af1),
then method 300 proceeds to step 472 where a first module (Set Module ID =
1) is identified as being the source or cause of the ACF. If the absolute value
of the difference between the common mode frequency (fcm) of the common
mode AC voltage signal (VCM) 125 and the first threshold frequency (fTH1) is
greater than or equal to the first frequency differential (Af1), then method 300
proceeds to step 364 where it is determined whether an absolute value of the
difference between the common mode frequency (fcm) and a second threshold
frequency (fTH2) is less than a second frequency differential (Δf2). If the
absolute value of the difference between the common mode frequency (fCM)
and the second threshold frequency (fTH2) is less than the second frequency
differential (Δf2), then method 300 proceeds to step 374 where a second
module (Set Module ID = 2) is identified as being the source or cause of the
ACF. If the absolute value of the difference between the common mode
frequency (fCM) and the second threshold frequency (fTH2) is greater than or
equal to the second frequency differential (Δf2), then method 300 proceeds to
step 366 where it is determined whether an absolute value of the difference
between the common mode frequency (fCM) and a third threshold frequency
(fTH3) is less than a third frequency differential (Δf3).
[0076] If the absolute value of the difference between the common mode
frequency (fCM) and the third threshold frequency (fTH3) is less than the third
frequency differential (Δf3), then method 300 proceeds to step 376 where a
third module (Set Module ID = 3) is identified as being the source or cause of
the ACF. If the absolute value of the difference between the common mode
frequency (fCM) and the third threshold frequency (fTH3) is greater than or
equal to the third frequency differential (Δf3), then method 300 loops back to
step 320. Although FIG. 3 illustrates three check steps 362, 364, 366 being
performed (i.e., when there are only three modules present that are potential
ACF sources), it will be appreciated that any number of checks can be
performed depending on the number of potential modules to be identified.

[0077] After identifying a module that is causing the ACF, the method 300
proceeds to step 380, where a fault counter (Nfault) is incremented. The fault
counter (Nfault) counts a number of consecutive particular periods during which
an ACF event is detected.
[0078] Method 300 then proceeds to step 385, where fault verification is
performed. At step 385, it is determined whether a count maintained by the
fault counter (Nfault), which indicates a number of consecutive ACF events
detected, is greater than or equal to is greater than or equal to a particular
threshold number (NTH) (e.g., 3). When the number of consecutive particular
periods during which an ACF-type pulse is received (Nfault) is greater than the
particular threshold number (NTH), detection of an ACF is verified. An actual
AC fault (ACF) exists when the count (Nfault) exceeds the particular threshold
number (NTH) (e.g., 3) since this means that the common mode AC voltage
signal 125 includes a continuous number of ACF-type pulses rather than an
intermittent or random ACF-type pulse. Counting a number of ACF events
reduces the likelihood of a false indicator, for instance, in a situation where a
single pulse occurs that is not associated with an actual ACF.
[0079] When it is determined at step 385 that the count maintained by the
fault counter (Nfault) is less than the particular threshold number (NTH) (e.g., 3),
the method 300 loops back to step 320, to continue monitoring the common
mode AC voltage signal (VCM) 125 for additional ACF voltage spikes.
Notably, if another spike is not detected at step 340 before reaching a
particular count, then the counter resets since the number of consecutive
particular periods during which the counter input signal is received is less than
a threshold number (NTH) (e.g., 3), and it can therefore be assumed that the
prior ACF-type pulses were intermittent or false fault indicators.
[0080] When it is determined at step 385 that the count maintained by the
fault counter (Nfault) is greater than the particular threshold number (NTH) (e.g.,
3), the ACF has been verified and the module which is the source or cause of
the ACF has been identified. The method 300 can then proceed to step 390.
At step 390, operation of the module causing the ACF can be stopped (e.g., the

module can turned off or disconnected from the high voltage DC bus 40), a
module identifier (ID) can be generated which identifies the module which is
causing the ACF and visually displayed on a user interface, and an audible
indicator can be generated which indicates the ACF condition and/or identifies
the module which is causing the ACF.
[0081] Some of the embodiments and implementations are described
above in terms of functional and/or logical block components and various
processing steps. However, it should be appreciated that such block
components may be realized by any number of hardware, software, and/or
firmware components configured to perform the specified functions. For
example, an embodiment of a system or a component may employ various
integrated circuit components, e.g., memory elements, digital signal
processing elements, logic elements, look-up tables, or the like, which may
carry out a variety of functions under the control of one or more
microprocessors or other control devices. In addition, those skilled in the art
will appreciate that embodiments described herein are merely exemplary
implementations.
[0082] In this document, relational terms such as first and second, and the
like may be used solely to distinguish one entity or action from another entity
or action without necessarily requiring or implying any actual such
relationship or order between such entities or actions. Furthermore, depending
on the context, words such as "connect" or "coupled to" used in describing a
relationship between different elements do not imply that a direct physical
connection must be made between these elements. For example, two elements
may be connected to each other physically, electronically, logically, or in any
other manner, through one or more additional elements.
While at least one exemplary embodiment has been presented in the foregoing
detailed description, it should be appreciated that a vast number of variations
exist. 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 the exemplary embodiment or
exemplary embodiments. It should be understood that various changes can be
made in the function and arrangement of elements without departing from the
scope of the invention as set forth in the appended claims and the legal
equivalents thereof.

CLAIMS
What is claimed is:
1. A circuit for detecting an AC fault (ACF) caused by a
module coupled to a bus of a hybrid/electric power train system, comprising:
a common mode voltage detector circuit designed to receive a high-
voltage DC input signal, and to generate a common mode AC voltage signal
(VCM) biased at approximately zero volts by removing a differential mode
voltage component from the high-voltage DC input signal; and
a magnitude detector coupled to the common mode voltage detector
circuit and designed to measure a magnitude of the common mode AC voltage
signal (VCM), determine whether a measured magnitude of the common mode
AC voltage signal (VCM) is greater than or equal to a fault detection threshold
voltage (VTH) and to generate an ACF detection signal when the measured
magnitude of the common mode AC voltage signal (VCM) is greater than or
equal to the fault detection threshold voltage (VTH)-
2. A circuit according to claim 1, wherein the circuit is also for
verifying the AC fault (ACF), and further comprising:
a fault verification unit, coupled to the magnitude detector, and
comprising:
a cycle counter designed to receive the ACF detection signal
and the common mode AC voltage signal (VCM), and wherein the cycle
counter comprises:
a register which maintains a count which indicates a
number of consecutive periods that the magnitude of the
common mode AC voltage signal (VCM) is greater than or equal
to the fault detection threshold voltage (VTH), wherein the cycle
counter increments the count maintained by the register each
time an ACF voltage spike is present in the common mode AC

voltage signal (VCM) while the cycle counter is enabled by the
ACF detection signal.
3. A circuit according to claim 2, wherein the cycle counter
generates a fault verification signal to indicate that detection of the ACF has
been verified when the count is greater than or equal to a particular threshold
number.
4. A circuit according to claim 3, wherein the count is greater
than or equal to a particular threshold number when the number of consecutive
periods during which an ACF voltage spike is detected is greater than or equal
to the particular threshold number thereby indicating that the common mode
AC voltage signal (VCM) includes a consecutive number of ACF pulses.
5. A circuit according to claim 2, wherein the cycle counter
resets the register when the fault voltage spikes are not greater than or equal to
VTH-
6. A circuit according to claim 1, wherein the circuit is also for
identifying the one of the modules which caused the AC fault (ACF), wherein
each module has a fundamental operating frequency (fCM) associated
therewith, and further comprising:
a detector designed to determine a frequency (f) of the common mode
AC voltage signal, and to generate a frequency (f) identification signal which
indicates a fundamental operating frequency (fCM) within the common mode
AC voltage signal.
7. A circuit according to claim 6, further comprising:
a module identification unit, coupled to the detector, and is designed to
receive the frequency (f) identification signal, to determine the one of the
modules that is the source of the ACF based on the fundamental operating

frequency (fCM) specified in the frequency (f) identification signal, and to
generate a module identification signal which identifies the one of the modules
that is the source of the ACF.
8. A circuit according to claim 7, wherein the module
identification unit comprises:
a lookup table which associates each module with a corresponding
operating frequency of that module, wherein the module identification unit
determines the one of the modules that is the source of the ACF based on the
fundamental operating frequency (fCM) specified in the frequency (f)
identification signal by performing a lookup in the lookup table.
9. A circuit according to claim 7, further comprising:
a fault indicator unit coupled to the fault verification unit and the
module identification unit, wherein the fault indicator unit receives the fault
verification signal and the module identification signal, and generates
information which identifies the module which is causing the ACF.
10. A circuit according to claim 9, wherein the information
comprises a fault indicator signal comprising an output fault code with a
corresponding module identifier (ID) which identifies the module which is
causing the ACF.
11. A hybrid/electric power train system, comprising:
a bus;
one or more modules coupled to the bus, wherein each module has a
fundamental operating frequency (fCM) associated therewith, wherein one of
the modules causes an AC fault (ACF); and
a circuit designed to detect an AC fault (ACF) caused by one of the
modules, the circuit comprising:

a common mode voltage detector circuit designed to generate a
common mode AC voltage signal (VCM) by removing a differential mode
voltage component from a DC input signal from the bus;
a magnitude detector coupled to the common mode voltage detector
circuit and designed to determine whether a measured magnitude of the
common mode AC voltage signal (VCM) is greater than or equal to a threshold
voltage (VTH), and to generate an AC fault (ACF) detection signal when the
measured magnitude of the common mode AC voltage signal (VCM) is greater
than or equal to the threshold voltage (VTH).
12. A system according to claim 11, further comprising:
a cycle counter, comprising:
a register designed to maintain a count which indicates a number of
consecutive periods that the magnitude of the common mode AC voltage
signal (VCM) is greater than or equal to the threshold voltage (VTH), and to
increment the count each time an ACF voltage spike is present in the common
mode AC voltage signal (VCM) while the cycle counter is enabled by the ACF
detection signal.
13. A system according to claim 12, wherein the cycle counter
is designed to generate a fault verification signal to indicate that detection of
the ACF has been verified when the count is greater than or equal to a
particular threshold number, wherein the count is greater than or equal to a
particular threshold number when the number of consecutive periods during
which an ACF voltage spike is detected is greater than or equal to the
particular threshold number thereby indicating that the common mode AC
voltage signal (VCM) includes a consecutive number of ACF pulses.

14. A system according to claim 12, wherein the ACF detection
signal is a counter enable signal, and wherein the register is designed to:
maintain a count which indicates a number of consecutive periods that
the magnitude of the common mode AC voltage signal (VCM) is greater than
or equal to the threshold voltage (VTH);
increment the count each time an ACF voltage spike is present in the
common mode AC voltage signal while the counter enable signal is being
received, and
wherein the cycle counter is designed to: generate a fault verification
signal to indicate that detection of the ACF has been verified when the count
is greater than or equal to a particular threshold number, wherein the count is
greater than or equal to a particular threshold number when the number of
consecutive periods during which an ACF voltage spike is detected is greater
than or equal to the particular threshold number thereby indicating that the
common mode AC voltage signal includes a consecutive number of ACF
pulses.
15. A system according to claim 11, wherein the circuit further
comprises:
a detector designed to determine a frequency (f) of the common mode
AC voltage signal, and to generate a frequency (f) identification signal which
indicates a fundamental operating frequency (fCM) within the common mode
AC voltage signal.
16. A system according to claim 15, wherein the circuit further
comprises:
a module identification unit designed to determine the one of the
modules that is the source of the ACF based on the fundamental operating
frequency (fCM) specified in the frequency (f) identification signal, and to
generate a module identification signal which identifies the one of the
modules that is the source of the ACF.

17. A system according to claim 16, wherein the circuit further
comprises:
a fault indicator unit coupled to the fault verification unit and the
module identification unit, wherein the fault indicator unit receives the fault
verification signal and the module identification signal, and generates
information which identifies the module which is causing the ACF based on
the fault verification signal and the module identification signal, wherein the
fault indicator information comprises an output fault code with a
corresponding module identifier (ID) which identifies the module which is
causing the ACF.
18. A system according to claim 11, further comprising:
a processor designed to process the fault indicator signal to generate a
signal which stops operation of the module causing the ACF.
19. A system according to claim 11, further comprising:
a display; and
a processor designed to process the fault indicator signal to generate a
signal which causes the display to visually display a module identifier (ID)
which identifies the module which is causing the ACF.
20. A system according to claim 11, further comprising:
an audio unit comprising a speaker; and
a processor designed to process the fault indicator signal to generate a
signal which causes the speaker to provide an audible indicator which
indicates the ACF.

Apparatus for AC fault (ACF) detection are provided. In addition, apparatus for AC fault (ACF) detection and verification are provided. In
addition, apparatus for identification of a module which is the cause of an AC fault (ACF) are provided. In one implementation, one or more of these apparatus can be combined to provide a fast, simple, low cost and reliable ACF detection, verification and/or identification circuit.

Documents:

2110-KOL-2008-(30-05-2014)-ABSTRACT.pdf

2110-KOL-2008-(30-05-2014)-CLAIMS.pdf

2110-KOL-2008-(30-05-2014)-CORRESPONDENCE.pdf

2110-KOL-2008-(30-05-2014)-DESCRIPTION (COMPLETE).pdf

2110-KOL-2008-(30-05-2014)-DRAWINGS.pdf

2110-KOL-2008-(30-05-2014)-FORM-1.pdf

2110-KOL-2008-(30-05-2014)-FORM-2.pdf

2110-KOL-2008-(30-05-2014)-FORM-3.pdf

2110-KOL-2008-(30-05-2014)-FORM-5.pdf

2110-KOL-2008-(30-05-2014)-OTHERS.pdf

2110-KOL-2008-(30-05-2014)-PA.pdf

2110-KOL-2008-(30-05-2014)-PETITION UNDER RULE 137.pdf

2110-kol-2008-abstract.pdf

2110-kol-2008-claims.pdf

2110-kol-2008-correspondence.pdf

2110-kol-2008-description (complete).pdf

2110-kol-2008-drawings.pdf

2110-kol-2008-form 1.pdf

2110-kol-2008-form 18.pdf

2110-kol-2008-form 2.pdf

2110-kol-2008-form 3.pdf

2110-kol-2008-form 5.pdf

2110-kol-2008-gpa.pdf

2110-kol-2008-specification.pdf

abstract_2110-kol-2008.jpg


Patent Number 264486
Indian Patent Application Number 2110/KOL/2008
PG Journal Number 01/2015
Publication Date 02-Jan-2015
Grant Date 31-Dec-2014
Date of Filing 04-Dec-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 CHANDRA S. NAMUDURI 5853 RUBY DRIVE TROY, MICHIGAN 48085
2 WILLIAM T IVAN 53784 TIDAL LANE SHELBY TOWNSHIP, MI 48316
PCT International Classification Number H05B37/00
PCT International Application Number N/A
PCT International Filing date
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 12/016,530 2008-01-18 U.S.A.