A built-in test circuit for testing a system timing margin of a processing device under-test is provided. The processing device includes a controller and first clock circuit, wherein the first clock circuit generates a first clock signal and the first clock signal is a main clock signal provided for operation of the processing device. The built-in test circuit includes a second clock circuit and a logic circuit, both of which are integrated with the processing device. The second clock circuit generates a second clock signal. The logic circuit processes the first and second clock signals and outputs a third clock signal. The third clock signal is used to determine system timing margin of the processing device.

The disclosure describes a novel method and apparatus for making device TAPs addressable to allow device TAPs to be accessed in a parallel arrangement without the need for having a unique TMS signal for each device TAP in the arrangement. According to the disclosure, device TAPs are addressed by inputting an address on the TDI input of devices on the falling edge of TCK. An address circuit within the device is associated with the device's TAP and responds to the address input to either enable or disable access of the device's TAP.

Described is an apparatus which comprises: a state detector which is operable to detect logic states of zero and one in response to a clock edge; and an error detector coupled to the state detector, wherein the error detector is to detect an error in the detected logic states.

The disclosure describes a novel method and apparatus for making device TAPs addressable to allow device TAPs to be accessed in a parallel arrangement without the need for having a unique TMS signal for each device TAP in the arrangement. According to the disclosure, device TAPs are addressed by inputting an address on the TDI input of devices on the falling edge of TCK. An address circuit within the device is associated with the device's TAP and responds to the address input to either enable or disable access of the device's TAP.

Various aspects include a clock monitoring unit/component that is configured to repeatedly/continuously monitor a clock with the speed required to support automobile automation systems without the use of a reference clock. The clock monitoring unit/component may be configured to identify, report, and/or respond to variations or abnormalities in the monitored clock, and initiate an action to prevent the variation from causing or resulting in a failure or a vulnerability to attack. The clock monitoring unit/component in the various aspects may be configured, organized, or arranged to operate so that the circuit is immune or resistant to manipulation, modification, tampering, hacks, and other attacks.

Testing of integrated circuits is achieved by a test architecture utilizing a scan frame input shift register, a scan frame output shift register, a test controller, and a test interface comprising a scan input, a scan clock, a test enable, and a scan output. Scan frames input to the scan frame input shift register contain a test stimulus data section and a test command section. Scan frames output from the scan frame output shift register contain a test response data section and, optionally, a section for outputting other data. The command section of the input scan frame controls the test architecture to execute a desired test operation.

According to one or more embodiments, the semiconductor integrated circuit device includes a pattern generator, a result comparator, and a control circuit. The pattern generator supplies input data to a device-under-test. The result comparator compares output data of the device-under-test with expected value data and outputs a test result signal. The control circuit controls the pattern generator and the result comparator. The device-under-test and the result comparator are commonly connected to a first clock line. The pattern generator and the control circuit are commonly connected to a second clock line different from the first clock line.

The disclosure relates to apparatus and methods for self-testing of a duty cycle detector. Example embodiments include a circuit (201) comprising: a clock signal generator (205) configured to provide an output clock signal (203) having a duty cycle; a duty cycle detector (208) arranged to receive the output clock signal (203) and provide an output flag if the duty cycle of the clock signal (203) is outside a predetermined range; a controller (214) arranged to provide a duty cycle select signal (216) to the clock signal generator (205) to cause the clock signal (203) to have a duty cycle outside the predetermined range and to receive the output flag to confirm operation of the duty cycle detector (208).

The disclosure provides a novel method and apparatus for inputting addresses to devices to select the device TAP for access. Further, the disclosure provides a novel method and apparatus for inputting addresses for selecting device TAPs and for inputting commands for commanding circuitry within the device. The inputting of addresses or the inputting of addresses and commands is initiated by a control bit input on TDI that is recognized during the Run Test/Idle, Pause-DR or Pause-IR TAP states.

The disclosure describes novel methods and apparatuses for accessing test compression architectures (TCA) in a device using either a parallel or serial access technique. The serial access technique may be controlled by a device tester or by a JTAG controller. Further the disclosure provides an approach to access the TCA of a device when the device exists in a daisy-chain arrangement with other devices, such as in a customer's system. Additional embodiments are also provided and described in the disclosure.