A semiconductor chip includes a first wireless communication circuit, a second wireless communication circuit, and an auxiliary path. The first wireless communication circuit includes a signal path, wherein the signal path includes a signal node. The second wireless communication circuit includes a mixer and a local oscillator (LO) buffer. The LO buffer is arranged to receive and buffer an LO signal, and is further arranged to provide the LO signal to the mixer. The auxiliary path is arranged to electrically connect the LO buffer to the signal node of the signal path, wherein the LO buffer is reused for a loop-back test function of the first wireless communication circuit through the auxiliary path.

An integrated circuit comprises a first functional unit and one or more other functional units. The first functional unit has an input for receiving data and an output for providing data. The integrated circuit tests and operates the first functional unit. Testing comprises: connecting the input of the first functional unit to the output of the first functional unit, thereby generating a loopback path from the output of the first functional unit to the input of the first functional unit; loading a test pattern onto the first functional unit; feeding a test clock signal comprising one or more clock edges, thereby prompting the first functional unit to transform the test pattern; and reading the transformed test pattern. Operating the first functional unit comprises: connecting the input of the first functional unit to an output of the other functional units; and feeding a normal clock signal to the first functional unit.

Presented embodiments facilitate efficient and effective flexible implementation of different types of testing procedures in a test system. In one embodiment, a test system comprises pre-qualifying test components, functional test components, a controller, a transceiver, and a switch. The pre-qualifying test components are configured to perform pre-qualifying testing on a device under test. The functional test components are configured to perform functional testing on the device under test. The controller is configured to direct selection between the pre-qualifying testing and functional testing. The transceiver is configured to transmit and receive signals to/from the device under test. The switch is configured to selectively couple the transceiver to the pre-qualifying test components and functional test components.

An embodiment of the present invention is an automated test equipment (ATE) for testing a device under test (DUT) which is connected to the ATE via a load board. The ATE comprises a stimulus module, a measurement module, a loopback, a first switch, a second switch, and a load board interface. The load board interface comprises a first radio frequency port and a second radio frequency port. The first and second radio frequency ports are configured to be coupled to the respective ports of the load board. The first switch is configured to couple the first radio frequency port to the stimulus module in a first switching state of the first switch and the second switch is configured to couple the second radio frequency port to the measurement module in a first switching state of the second switch. Further, the first switch is configured to couple the first radio frequency port to a first end of the loopback in a second switching state of the first switch and the second switch is configured to couple the second radio frequency port to a second end of the loopback in a second switching state of the second switch. When the first and second switches are in their respective second switching state, a loopback signal path is formed between the first and second radio frequency ports.

An electronic chip includes an analog input connection pad and an analog output connection pad. A switch is coupled between the analog input connection pad and the analog output connection pad. In one embodiment, the chip operates in a self-test mode and in an active mode. The switch is closed only in the self-test mode.

An integrated circuit includes a serializer configured to receive first test data in n-bit words and to generate a single bit data stream by serializing the test data in accordance with a first clock signal. The integrated circuit includes testing circuitry configured to test the serial izer without utilizing a deserializer.

Presented embodiments facilitate efficient and effective flexible implementation of different types of testing procedures in a test system. In one embodiment, a test system comprises pre-qualifying test components, functional test components, a controller, a transceiver, and a switch. The pre-qualifying test components are configured to perform pre-qualifying testing on a device under test. The functional test components are configured to perform functional testing on the device under test. The controller is configured to direct selection between the pre-qualifying testing and functional testing. The transceiver is configured to transmit and receive signals to/from the device under test. The switch is configured to selectively couple the transceiver to the pre-qualifying test components and functional test components.

One embodiment of the present disclosure describes a memory system that may include one or more memory devices that may store data. The memory devices may receive command signals to access the stored data as a loopback signal. The memory devices may operate in a normal operational mode, a loopback operational mode, a retrieval operational mode, a non-inverting pass-through operational sub-mode, and an inverting pass-through operational sub-mode. The operational modes facilitate the transmission of the loopback signal for the purpose of monitoring of memory device operations. A selective inversion technique, which uses the operational modes, may protect the loopback signal integrity during transmission.

A semiconductor chip includes a first wireless communication circuit, a local oscillator (LO) buffer, and an auxiliary path. The first wireless communication circuit has a signal path, wherein the signal path has a mixer input port and a signal node distinct from the mixer input port. The auxiliary path is used to electrically connect the LO buffer to the signal node of the signal path. The LO buffer is reused for a loop-back test function through the auxiliary path.

A testing device includes a transmitter circuit, a receiver circuit, and a loopback circuit. The transmitter circuit is configured to receive a plurality of first test signals. The receiver circuit is configured to receive input data from a plurality of pads in a normal mode. The loopback circuit is coupled to the plurality of pads and input terminals of a sampler circuit, and the loopback circuit is configured to transmit the plurality of first test signals from the transmitter circuit to the input terminals of the sampler circuit, in order to generate test data for subsequent analysis.