Abstract: An amplifier. The novel amplifier includes a first circuit for receiving and amplifying an input signal and outputting an output signal, and a second circuit for supplying power to the first circuit, wherein the power supplied varies in accordance with variations in the output signal. The second circuit includes a bootstrapping circuit adapted to regulate the voltages across any transistors in the signal path such that the voltages remain constant. In an illustrative embodiment, the second circuit bootstraps the voltages across a PMOS current source that acts as the load to an input stage, as well as a Darlington pair in an output stage of the amplifier.

Abstract: Multi-layer metal-shielded monolithic transmission lines are formed in side-by-side arrangement by depositing parallel planar thin film, conductive layers, separated by nonconductive separator layers to form a stack of alternating conductive and nonconductive layers. The conductive layers form a top and a bottom conductive plane and establish a mutually registered selected width of the stack. A center conductive layer has laterally spaced apart conductive strips separated by nonconductive spacer layers. The two laterally terminal of the conductive strips are spaced at the selected width. Each of the nonconductive separator layers provides a plurality of elongated vias between the two lateral terminals of the three conductive strips and the conductive planes.

Abstract: A signal processing system and method. The inventive system includes a first circuit for distributing an input signal between two or more channels in a current mode of operation. A second circuit is disposed in each of the channels for processing the input signal and providing an output signal in response thereto. A third circuit is provided to combine the signals output by the processing circuit. A fourth circuit is included for controlling the first and the third circuits. In a specific illustrative embodiment, the system further includes a radio frequency stage for downconverting a received signal and providing the input signal in response thereto. In the specific embodiment, the first circuit includes a mixing circuit. The mixing circuit includes Gilbert cells and circuitry for providing automatic gain control for each of the channels individually. The Gilbert cells and the automatic gain control circuitry are driven by a transconductance amplifier and therefore operate in a current mode.

Abstract: A crosspoint switch architecture (10). The inventive architecture (10) includes a monolithic substrate (11) on which a plurality (N) of electrical inputs are provided. In addition, a plurality (M) of electrical outputs are provided on the substrate (11). A switch is disposed on the substrate (11) for selectively interconnecting the inputs to the outputs and a control circuit (16) is disposed on the substrate (11) for controlling the switch. The switch comprises M, N to 1, multiplexers (14), each multiplexer (14) being adapted to receive each of the N electrical inputs. In the illustrative embodiment, each of the N inputs to each of the multiplexers is received through a respective one of N switchable amplifiers (18). The output of each amplifier (18) is provided to a respective one of N switchable isolation buffers (19). The outputs of the buffers (19) are summed and buffered to provide the output of each multiplexer (14).

Abstract: A subranging analog to digital converter (ADC). The ADC (200) includes a novel resistive ladder (56) for a differential quantizer (50) and a novel summing node circuit (150). The novel resistive ladder (56) includes an input terminal (52), a plurality of serially connected resistors R coupled to the input terminal (52), and a pair of complementary current sources (66 and 68) for maintaining a constant current flow through the ladder (56). The novel summing node circuit (150) includes an input terminal (152) for receiving an input signal, a pair of complementary DACs (156 and 158) for generating a reconstruction signal, and a summing amplifier (164) for subtracting the reconstruction signal from the input signal to produce a residue signal. The invention also includes a method for trimming the subranging ADC.

Abstract: A DAC (10) including an operational amplifier (12) having an input terminal; a plurality of current paths coupled to the input terminal; a plurality of current sources (I1/2 -I4/2); and an arrangement (11) for switchably coupling current from at least two of the cells to a respective one of the paths in response to an input signal. In a specific embodiment, the inventive DAC (10) further includes a first resistive element (2R1-2R4) disposed in each of the current paths, a second resistive element (R1-R4) disposed between the current paths, and a feedback resistor (RF) disposed between an output terminal of the amplifier and the input terminal thereof. In the illustrative embodiment, the coupling arrangement includes a plurality of switches (SW1-SW4); each of the switches is adapted to switch half of the current from a first source and half of the current from a second source into a respective one of the paths.

Abstract: A digitally trimmed current source. The novel current source includes a first circuit for generating a current in response to an applied voltage and a resistance variable in response to a control signal, and a second circuit for supplying the control signal. The first circuit includes a resistive network comprised of a plurality of resistors; a plurality of switches, each switch coupled to one of the resistors and adapted to selectively switch the resistor in and out of the resistive network in response to the control signal; and a transistor adapted to apply a voltage across the resistive network to generate a current.

Abstract: A current switch. The novel current switch includes a differential pair of transistors Q1 and Q2, a pair of cascode transistors QA and QB coupled to Q1 and Q2, respectively, and a circuit for maintaining QA and QB in an ‘on’ state regardless of the states of Q1 and Q2. The circuit for keeping QA and QB on includes first and second current sources adapted to supply first and second trickle currents to the emitters of QA and QB, respectively. The bases of QA and QB are connected in common to a voltage source VREF4, which, in an illustrative embodiment, is implemented using a Schottky diode for lower impedance. The circuit for driving Q1 and Q2 may also be implemented using a current switch with trickle current, cascode transistors Q14 and Q15 to further improve settling times.

Abstract: A system and method for sampling and holding a signal. The invention includes a novel input circuit for a track and hold circuit comprising a circuit Q1 for receiving an input signal including an input node, a first output node N1, and a path connecting the input and output nodes; a current switching circuit for applying a first current to the node N1 during a first mode of operation but not during a second mode; and a current source for applying a second current to the node N1 during both of the first and second modes. The value of the first current is determined such that the total current in the path is constant during the first and second modes. In an illustrative embodiment, the first mode is a track mode and the second mode is a hold mode.

Abstract: An Advanced Digital Antenna Module (ADAM) for receiving and exciting electromagnetic signals. The ADAM ASIC integrates a complete receiver/exciter function on a monolithic SiGe device, enabling direct digital-to-RF (Radio Frequency) and RF-to-digital transformations. The invention includes an improved analog-to-digital converter (ADC) (10) with a novel active offset method for comparators. The novel ADC architecture (10) includes a first circuit (12, 14) for receiving an input signal; a second circuit (18) for setting a predetermined number of thresholds using a predetermined number of preamplifiers (60) with weighted unit current sources (66) in each of the preamplifier outputs; and a third circuit (20) for comparing the input to the thresholds. In the preferred embodiment, the ADC (10) includes trimmable current sources (66). The ADC (10) of the present invention also includes an improved comparator circuit (62).

Abstract: An Advanced Digital Antenna Module (ADAM) for receiving and exciting electromagnetic signals. The ADAM ASIC integrates a complete receiver/exciter function on a monolithic SiGe device, enabling direct digital-to-RF (Radio Frequency) and RF-to-digital transformations. The invention includes an improved analog-to-digital converter (ADC) (10) with a novel active offset method for comparators. The novel ADC architecture (10) includes a first circuit (12, 14) for receiving an input signal; a second circuit (18) for setting a predetermined number of thresholds using a predetermined number of preamplifiers (60) with weighted unit current sources (66) in each of the preamplifier outputs; and a third circuit (20) for comparing the input to the thresholds. In the preferred embodiment, the ADC (10) includes trimmable current sources (66). The ADC (10) of the present invention also includes an improved comparator circuit (62).

Abstract: An active load circuit for automatic test equipment that tests integrated circuits. The active load circuit includes a current source; a current sink; a current switching switching circuit having current source and current sink nodes respectively connected to the current source and the current sink; and a control circuit for controlling the current switching circuit with a differential voltage that is limited in amplitude and of the same polarity as a voltage difference between a fixed reference voltage and a pin output voltage of a device under test.

Abstract: A wideband fast-hopping receiver front-end uses direct digital synthesis (DDS) to provide quadrature LO signals to the front-end's mixers. A DDS circuit stores multiple digital word sequences which represent desired waveforms, and outputs desired sequence pairs to a pair of DACs in response to a clock signal and a command signal. The DACs convert the sequences to analog signals, which are filtered and squared as necessary to provide quadrature LO signals to the mixers. Frequency hopping is accomplished by changing the command signal, which causes a different pair of sequences to be output and the frequency of the LO signals provided to the mixers to be changed. Active image rejection is combined with DDS LO generation to provide faster frequency hopping. The front-end is combined with an ADC and a communications signal processor to provide a complete system, all of which can be integrated together on a common substrate.

Abstract: A mixed technology microcircuit including a first circuit fabricated on a first layer with a first technology and a second circuit fabricated on a second layer with a second technology. In the illustrative embodiment, the first circuit is fabricated with silicon germanium (SiGe) technology and the second circuit is fabricated with complementary metal-oxide semiconductor (CMOS) technology. In an illustrative application, the first circuit includes a high-speed data receiver and a high-speed data transmitter. In the illustrative implementation, the data receiver includes a line receiver, a data and clock recovery circuit, and a demultiplexer and the data transmitter includes a multiplexer, a data and clock encoding circuit, and a line driver.

Abstract: A system and method for effecting wideband image rejection. In a receiver implementation, the inventive method includes the steps of receiving a first signal in a first frequency band and generating in-phase and quadrature signals therefrom. The phase of the in-phase signal is shifted to provide a second signal and the phase of the quadrature signal is shifted to provide a third signal. A predetermined phase relationship is thereby effected between the second and the third signals. The second and third signals are then summed to provide an output signal which has minimal interference from a mixing signal. In an illustrative receiver application, the phase shifting is achieved via the use of all pass networks. Each of the all pass networks include a differential amplifier having first and second input terminals. The first and the second terminals are connected to a first end of first and second resistive elements, respectively.

Abstract: A high performance ADC apparatus. The inventive apparatus comprises a front end ADC baseline device providing a baseline bit size at a baseline data rate and a selected dynamic range at a baseline clock rate. A first circuit is enabled for translating upward, by a selected factor, a reference clock to produce the baseline clock rate. A second circuit is enabled for decimating the baseline data rate of the baseline device to a data rate reduced by the selected factor, so as to achieve an oversampling rate equal to the selected factor. A final circuit is employed for producing an output data rate less than the baseline clock rate by the selected factor with the final resolution.

Abstract: A method of integrating MEMS devices with non-MEMS circuitry requires fabricating non-MEMS devices on a substrate in a conventional fashion. A thick dielectric layer is deposited on the completed devices, and the MEMS devices fabricated on the dielectric layer. Vias through the dielectric layer interconnect the MEMS devices to the non-MEMS electronics. The interposed dielectric layer allows the common substrate to have characteristics that best suit the non-MEMS components, without degrading the MEMS performance. Another approach involves bonding together two separate wafers—one for the MEMS devices and one for non-MEMS electronics. A package lid, having filled vias formed therethrough, is bonded to the MEMS wafer, sealing the MEMS devices within. The non-MEMS wafer is mounted to the lid, with the vias effecting the necessary interconnections between the two wafers.

Abstract: A unit cell including a substrate; an active circuit disposed on the substrate; and an arrangement disposed on the substrate for routing a plurality of conductors thereover. In the illustrative implementation, the routing arrangement includes first, second and third ground planes disposed on the substrate, a first layer of conductors disposed between the first and second planes, and a second layer of conductors disposed between the second and the third planes. Each cell is adapted to connect to a device such as a detector. The inventive unit cell enables an improved focal plane array design with a smaller unit cell supporting smaller detector sizes. Smaller detector pitch allows higher density detector arrays. The inventive fan-out approach allows for complicated circuitry to be located outside the array. This permits the utilization of more sophisticated analog signed processing, such as a multiple sample approach.

Abstract: A method of integrating MEMS devices with non-MEMS circuitry requires fabricating non-MEMS devices on a substrate in a conventional fashion. A thick dielectric layer is deposited on the completed devices, and the MEMS devices fabricated on the dielectric layer. Vias through the dielectric layer interconnect the MEMS devices to the non-MEMS electronics. The interposed dielectric layer allows the common substrate to have characteristics that best suit the non-MEMS components, without degrading the MEMS performance. Another approach involves bonding together two separate wafers—one for the MEMS devices and one for non-MEMS electronics. A package lid, having filled vias formed therethrough, is bonded to the MEMS wafer, sealing the MEMS devices within. The non-MEMS wafer is mounted to the lid, with the vias effecting the necessary interconnections between the two wafers.

Abstract: Arrangements of Class AB (push-pull) amplifiers, one in a higher voltage configuration and one in a lower voltage configuration, to achieve a high intercept at low power as well as a low noise figure in a complementary technology allowing for higher performance at lower power. In an illustrative embodiment, the invention includes a first circuit for receiving an input signal; a second circuit for shifting a level of the input signal; and a third circuit for amplifying the input signal. In the illustrative embodiment, the third circuit includes first and second transistors Q3 and Q4 connected in a push-pull configuration. In the illustrative embodiment, the first and second transistors Q3 and Q4 are connected to form Class AB amplifiers and the first transistor Q3 is of a first type and the second transistor Q4 is of a second type. The teachings of the present invention are illustrated in a differential amplifier.