Patent application number | Description | Published |
20080225566 | Using eFuses to Store PLL Configuration Data - A mechanism for using electrical fuses (eFuses) to store phase-locked loop (PLL) configuration data are provided. With the mechanism, a portion of the eFuses present in the integrated circuit are reserved for the PLL configuration data. Upon power up, a power up controller and eFuse controller direct the sensing and serial transfer of the data in the portion of eFuses to the PLL under the reference clock. When the transfer is complete, the power up controller directs the PLL logic to load the configuration data and start. The mechanism of the present invention allows manufacturing to tailor the PLL configuration on a given device based on the characteristics of that device and its intended usage. Thus, the same PLL may be used in the same or different architectures to perform different operations based on the configuration data passed into the PLL from the eFuses. | 09-18-2008 |
20080229136 | Controlling Asynchronous Clock Domains to Perform Synchronous Operations - A mechanism for controlling asynchronous clock domains to perform synchronous operations is provided. With the mechanism, when a synchronous operation is to be performed on a chip, the latches of the functional elements of the chip are controlled by a synchronous clock so that the latches are controlled synchronously even across asynchronous boundaries of the chip. The synchronous operation may then be performed and the chip's functional elements returned to being controlled by a local clock in an asynchronous manner after completion of the synchronous operation. This synchronous operation may be, for example, a power on reset (POR) operation a manufacturing test sequence, debug operation, or the like. | 09-18-2008 |
20080320349 | eFuse Programming Data Alignment Verification Apparatus and Method - An eFuse data alignment verification apparatus and method are provided. Alignment latches are provided in a series of latch units of a write scan chain and a logic unit is coupled to the alignment latches. A sequence of data that is scanned-into the series of latch units of the write scan chain preferably includes alignment data values. These alignment data values are placed in positions within the sequence of data that, if the sequence of data is properly scanned-into the series of latch units, cause the data values to be stored in the alignment latches. The logic unit receives data signals from the alignment latches and determines if the proper pattern of data values is stored in the alignment latches. If the proper pattern of data values is present in the alignment latches, then the data is aligned and a program enable signal is sent to the bank of eFuses. | 12-25-2008 |
20090055637 | SECURE POWER-ON RESET ENGINE - A secure Power-on Reset (POR) engine is provided, inside a processor chip, which guarantees a secure initialization of the chip to enable secure code execution. External access to chip resources is limited to a very few targeted settings that do not compromise the chip security. The POR engine comprises a small state machine that runs through a predefined sequence coded in persistent memory contained in the processor chip. The state machine initializes the chip and allows external access from an external processor to only some scan chains of the processor chip in order to configure interfaces, and the like, without compromising the chip security. The state machine also manages the encryption keys that are used to verify that the code, fetched by the processor to complete the initialization in software, is not modified by a third party. | 02-26-2009 |
20090083594 | Testing Functional Boundary Logic at Asynchronous Clock Boundaries of an Integrated Circuit Device - Mechanisms for testing functional boundary logic at an asynchronous clock boundary of an integrated circuit device are provided. With these mechanisms, each clock domain has its own scan paths that do not cross domain boundaries. By eliminating the scanning across the boundaries, the requirement to have two clock grids in the asynchronously clocked domains may be eliminated. As a result, circuit area and design time with regard to the clock distribution design are reduced. In addition, removing the second clock grid, i.e. the high speed core or system clock, in the asynchronously clocked domains removes the requirement to have a multiplexing scheme for selection of clocking signals in the asynchronous domain. In addition to the above, the system and method provide boundary built-in-self-test logic for testing the functional crossing logic of boundaries between the clock domains in a functional mode of operation. | 03-26-2009 |
20090089636 | Method and Apparatus for Logic Built In Self Test (LBIST) Fault Detection in Multi-Core Processors - A method, system, and computer program product for identifying failures in multi-core processors, utilizing logic built-in self test (LBIST) technology. Multi-core processors, having LBIST and pseudo-random pattern generator (PRPG) circuitry, are tested. Controlled by the LBIST control logic, PRPG inputs a test pattern into scan chains within the cores of each device. A new test pattern is generated and executed during the scan shift phase of each LBIST loop. Logic output generated by each scan chain in the core is compared to other core logic output. Failures within the multi-core processors are determined by whether the logic output generated from a core, within a latch sequence, does not match the logic output of the other cores. If logic output, from a core within a latch sequence, does not match, then the latch number, loop number, and latch values are recorded as failed. | 04-02-2009 |
20090106575 | Controlling Asynchronous Clock Domains to Perform Synchronous Operations - Mechanisms for controlling asynchronous clock domains to perform synchronous operations are provided. With these mechanisms, when a synchronous operation is to be performed on a chip, the latches of the functional elements of the chip are controlled by a synchronous clock so that the latches are controlled synchronously even across asynchronous boundaries of the chip. The synchronous operation may then be performed and the chip's functional elements returned to being controlled by a local clock in an asynchronous manner after completion of the synchronous operation. This synchronous operation may be, for example, a power on reset (POR) operation, a manufacturing test sequence, debug operation, or the like. | 04-23-2009 |
20090125267 | Digital Thermal Sensor Test Implementation Without Using Main Core Voltage Supply - A method and apparatus are provided for calibrating digital thermal sensors. A processor chip with a plurality of digital thermal sensors receives an analog voltage. A test circuit coupled to the processor chip receives a clock signal and a register coupled to the test circuit outputs a value on each clock cycle to a digital thermal sensor in the plurality of digital thermal sensors. The digital thermal sensor transitions an output state in response to the value of the register received in the digital thermal sensor equaling a temperature threshold of the digital thermal sensor. The value of the register at the point of transition is used to calibrate the digital thermal sensor. An incrementer increments the value of the register on each clock cycle in response to the value of the register received in the digital thermal sensor failing to equal the temperature threshold of the digital thermal sensor. | 05-14-2009 |
20100100357 | Information Collection and Storage for Single Core Chips to 'N Core Chips - Provided is a method for the collection and storage of information related to the operation of a chip module. The disclosed technology provides a chip data collection and storage controller. In one embodiment, a chip module is provided with a stand-alone memory that records information relevant to potential debugging operations. The stand-alone memory is on the same chip module as the chip die but is not part of the chip die. A data bus is provided between the chip module and the memory. In addition, the memory has I/O access so that information can be accessed in the event that the chip module cannot be accessed. Stored information includes, but is not limited to, environmental conditions, performance information, errors, time usage, run time, number of power on cycles, the highest temperature experience by the chip, wafer and x, y data, manufacturing info, FIR errors, and PRSO, SRAM PSRO values. | 04-22-2010 |
20140053034 | ON-CHIP DETECTION OF TYPES OF OPERATIONS TESTED BY AN LBIST - An integrated circuit includes an LBIST controller operative to run a test program on at least one selection of core logic of the integrated circuit to test the operability of the at least one selection of core logic. The integrated circuit also includes a monitoring logic structure operative to detect at least one type of operation executed for the test program from at least one particular control signal activated by the LBIST controller for controlling the at least one selection of core logic to execute the test program from among at least one control signal for controlling operations on the at least one selection of core logic. | 02-20-2014 |
20140053035 | ON-CHIP DETECTION OF TYPES OF OPERATIONS TESTED BY AN LBIST - An integrated circuit includes an LBIST controller operative to run a test program on at least one selection of core logic of the integrated circuit to test the operability of the at least one selection of core logic. The integrated circuit also includes a monitoring logic structure operative to detect at least one type of operation executed for the test program from at least one particular control signal activated by the LBIST controller for controlling the at least one selection of core logic to execute the test program from among at least one control signal for controlling operations on the at least one selection of core logic. | 02-20-2014 |
20140149814 | Isolating Failing Latches Using a Logic Built-In Self-Test - A mechanism is provided for identifying a failing latch within an integrated circuit device. A test sequence is initiated on a set of scan chains associated with an identified failing multiple input signature register. For each test portion in a set of test portions in the test sequence, a comparison is performed between an output of the multiple input signature register and a corresponding value in a set of expected values. Responsive to determining a match, a value of a counter is incremented. Responsive to a failure to match, incrementing of the counter is stopped, and the value of the counter providing an indication of the failing latch in the integrated circuit device is read out. | 05-29-2014 |