Abstract: An apparatus, method, and computer program product to identify types of errors that occur in a communications device under test and where only the presence of an error is indicated by an error checker. Each presence of an error bit in an error signal during a first period of time output from the error data checker is identified. The error bit indicates only that a mismatch occurred between an input signal input into the device and an output signal output from the device. The error bit is generated in response to an error in the device under test. The error bit includes no information about a type of the error. The type of the error is determined by determining a number of occurrences of the error bit in the error signal during the first period of time.

Abstract: Self-synchronizing techniques for checking the accuracy of a pseudorandom bit sequence (PRBS) are provided. The PRBS being checked may be generated by a device (e.g., a device under test) in response to a PRBS received by the device (e.g., from a PRBS generator). In an aspect of the invention, a PRBS checking technique includes the following steps/operations. For a given clock cycle, the presence of an error bit in the PRBS generated by the device is detected. The error bit represents a mismatch between the PRBS input to the device and the PRBS output from the device. Then, propagation of the error bit is prohibited for subsequent clock cycles. The prohibition step/operation may serve to avoid multiple errors being counted for a single error occurrence and/or masking errors in the PRBS output by the device.

Abstract: Self-synchronizing techniques for checking the accuracy of a pseudorandom bit sequence (PRBS) are provided. The PRBS being checked may be generated by a device (e.g., a device under test) in response to a PRBS received by the device (e.g., from a PRBS generator). In an aspect of the invention, a PRBS checking technique includes the following steps/operations. For a given clock cycle, the presence of an error bit in the PRBS generated by the device is detected. The error bit represents a mismatch between the PRBS input to the device and the PRBS output from the device. Then, propagation of the error bit is prohibited for subsequent clock cycles. The prohibition step/operation may serve to avoid multiple errors being counted for a single error occurrence and/or masking errors in the PRBS output by the device.

Abstract: A testable digital delay line that uses XOR gates as delay elements is provided. The use of XOR gates enables independent control of each input to the multiplexer. With test inputs that enable each delay element, the multiplexer inputs can be assigned any value during test, thus giving the delay line very robust pattern fault coverage. The XOR gate may consist of three current limiting inverters. A reference voltage generator generates constant voltages between a source voltage, bias voltages, and ground. These constant voltages decide the amount of current through the current limiting inverters. Selecting a different set of reference voltages programs a different current flowing in the current limiting inverters. This programmable current causes a programmable unit delay to be introduced by each XOR gate delay element.

Abstract: A testable digital delay line that uses XOR gates as delay elements is provided. The use of XOR gates enables independent control of each input to the multiplexer. With test inputs that enable each delay element, the multiplexer inputs can be assigned any value during test, thus giving the delay line very robust pattern fault coverage. The XOR gate may consist of three current limiting inverters. A reference voltage generator generates constant voltages between a source voltage, bias voltages, and ground. These constant voltages decide the amount of current through the current limiting inverters. Selecting a different set of reference voltages programs a different current flowing in the current limiting inverters. This programmable current causes a programmable unit delay to be introduced by each XOR gate delay element.

Abstract: A testable digital delay line that uses XOR gates as delay elements is provided. The use of XOR gates enables independent control of each input to the multiplexer. With test inputs that enable each delay element, the multiplexer inputs can be assigned any value during test, thus giving the delay line very robust pattern fault coverage. The XOR gate may consist of three current limiting inverters. A reference voltage generator generates constant voltages between a source voltage, bias voltages, and ground. These constant voltages decide the amount of current through the current limiting inverters. Selecting a different set of reference voltages programs a different current flowing in the current limiting inverters. This programmable current causes a programmable unit delay to be introduced by each XOR gate delay element.

Abstract: An apparatus, method, and computer program product are disclosed for identifying types of errors that occur in a communications device under test and where only the presence of an error is indicated by an error checker. Each presence of an error bit in an error signal during a first period of time output from the error data checker is identified. The error bit indicates only that a mismatch occurred between an input signal input into the device and an output signal output from the device. The error bit is generated in response to an error in the device under test. The error bit includes no information about a type of the error. The type of the error is determined by determining a number of occurrences of the error bit in the error signal during the first period of time.

Abstract: Techniques for scaling and switching clocks in a glitch-free manner are provided. For example, in one aspect of the present invention, a technique for switching a frequency associated with a master clock includes the following steps/operations. Two phase clocks are generated from a master clock, wherein the two phase clocks do not transition at substantially the same time. Then, one of the two phase clocks is used to create multiple frequencies by dividing the one phase clock, and the other phase clock is used to switch between the multiple frequencies of the one phase clock. Further, one of the two phase clocks may be in phase with the master clock and the other of the two phase clocks may be 180 degrees out of phase with the master clock such that they do not transition at the same time. Also, the two phase clocks may be non-overlapping.

Abstract: Self-synchronizing techniques for checking the accuracy of a pseudorandom bit sequence (PRBS) are provided. The PRBS being checked may be generated by a device (e.g., a device under test) in response to a PRBS received by the device (e.g., from a PRBS generator). In an aspect of the invention, a PRBS checking technique includes the following steps/operations. For a given clock cycle, the presence of an error bit in the PRBS generated by the device is detected. The error bit represents a mismatch between the PRBS input to the device and the PRBS output from the device. Then, propagation of the error bit is prohibited for subsequent clock cycles. The prohibition step/operation may serve to avoid multiple errors being counted for a single error occurrence and/or masking errors in the PRBS output by the device.