Abstract: An RMS-DC converter generates a series of progressively amplified signal pairs which are then multiplied and weighted in such a way as to cancel uncorrelated noise while still providing true square-law response. The converter includes two series of gain stages for generating the amplified signal pairs, and a series of four-quadrant multipliers for multiplying and weighting the amplified signal pairs in response to a series of weighting signals. The outputs from the multipliers are summed and averaged, and a final output signal is generated by integrating the difference between the averaged signal and a reference signal. To preserve the square-law response over a wide range of input voltages, the system is servoed by feeding the final output signal back to an interpolator which generates the weighting signals as a series of continuously interpolated, overlapping, Gaussian-shaped current pulses having a centroid that moves along the length of the interpolator as the final output signal varies.

Abstract: An RMS-DC converter provides extended dynamic range by driving a squaring cell with a variable gain amplifier. Temperature effects in the squaring cell can be cancelled by driving a second squaring cell with a reference signal and averaging the difference between the output signals from the two squaring cells. In a transmission system utilizing a power measurement system having two detector cells, square-law conformance errors in the detector cells can be cancelled by driving one of the detectors cells with a replica of the baseband modulation signal.

Abstract: A high-frequency RMS-DC converter having extended dynamic range operates by dynamically at low cost by adjusting the scaling factor (denominator) of a detector cell such as a squaring cell. The output from the squaring cell is averaged to generate a final output signal which can be fed back to a scaling input for operation in a measurement mode, or used to drive a power amplifier in a controller mode. By implementing the squaring cell as a transconductance cell using a modified multi-tanh structure, the scaling factor can be adjusted by dynamically changing the tail current through the cell which, in the measurement mode, is achieved by connecting the averaged output back to the squaring cell. An exponentially responding amplifier can be used in the feedback loop to provide a linear-in-dB output characteristic.

Abstract: An RMS-to-DC converter implements the difference-of-squares function by utilizing two identical squaring cells operating in opposition to generate two signals. An error amplifier nulls the difference between the signals. When used in a measurement mode, one of the squaring cells receives the signal to be measured, and the output of the error amplifier, which provides a measure of the RMS value of the input signal, is connected to the input of the second squaring cell, thereby closing the feedback loop around the second squaring cell. When used in a control mode, a set-point signal is applied to the second squaring cell, and the output of the error amplifier is used to control a variable-gain device such as a power amplifier which provides the input to the first squaring cell, thereby closing the feedback loop around the first squaring cell.

Abstract: An RMS-to-DC converter implements the difference of squares function using two squaring cells operating in opposition to attain a balance. Each of the squaring cells is implemented as a grounded-base transistor and a two-transistor current mirror. The emitter of the grounded-base transistor is coupled to the input terminal of the current mirror at a node which receives the input signal. The collector of the grounded-base transistor and the output of current mirror are coupled together to generate an output current having a square-law relationship to the input signal. One of the squaring cells receives the input signal and operates at high frequencies (HF), while the other receives a feedback signal and operates in a quasi-DC mode. In a measurement node, a nulling circuit closes a feedback loop around the DC squaring cell to null the output currents from the squaring cells.

Abstract: A progressive-compression logarithmic amplifier, amplifier stage, and method for increasing the bandwidth of a differential-input progressive-compression logarithmic amplifier are disclosed. The amplifier stage provides positive gain increases for decreases in the impedance of the load driven by the stage. When multiple amplifier stages of this type are cascaded, the gain increase in each stage compensates for high-frequency roll-off due to the input capacitance of the following stage. The compensating is activated by the roll-off effect itself, making the device self-compensating. This is preferably accomplished by providing a drive current sensing path that makes each node of the stage's differential output respond in opposition to the drive current drawn at the stage's other differential output--that is, an increase in drive current at one output node drops the voltage at the other output node.

Abstract: An RF mixer provides extended dynamic range with reduced noise by utilizing degeneration inductors in the RF input section of a doubly balanced mixer. Degeneration inductors are also utilized in a mixer having a class AB input section. A current mirror in the class AB input section is also inductively degenerated for further noise reduction. The input section is biased by an all-NPN bandgap reference cell which is tightly integrated into the input section so as to reduce the power supply voltage required for the reference cell. The mixer can be optimized for wide input voltage ranges or low distortion.

Abstract: Offset racing rail arrangements (16) of the fixed and relocatable variety are made safer by fitment of a cover designed to prevent riders from falling between and sometimes onto the poles which support the racing rail. A cover (22) is provided which is releasably attachable to a receptacle portion of the rail which is also resiliently spaced by a support means from the posts (10) which support the rail. The cover (22) is one embodiment comprises sheet material (24) bent (30, 32, 34, 36 and 38) underneath itself in such a manner as to provide a resilient self supporting spacing from each posts (10). The cover (22) is also in the embodiment provided with an edge portion (26) adapted to releasbly attach to a receptacle portion (56) of the rail without the use of fasteners.

Abstract: A rail-to-rail output circuit synthesizes a constant product output characteristic by replicating the current through a pull-up transistor and utilizing a translinear loop to drive a complementary pull-down transistor responsive to the replicated current. A smaller replication transistor shares a common V.sub.BE with the pull-up transistor so as to generate a scaled replication current that is proportional to the current through the pull-up transistor. The replication transistor is coupled to the base of the pull-down transistor through a bias circuit that forms a fast translinear loop with the pull-down transistor. An emitter follower transistor sevoes the loop so that the product of the currents through the pull-up and pull-down transistors is proportional to the square of a bias current. To reduce the turn-off time of the pull-down transistor, a second replication transistor is be connected with its base-emitter junction sharing the V.sub.

Abstract: Multi-tanh cells constructed in accordance with the present invention provide improved input voltage range by utilizing resistors connected between the emitters of the transistors and the corresponding bias current sources. The resistor values and emitter area ratios are chosen to achieve substantially distortion-free transconductance functions over wide input voltage ranges. This improved input voltage range results in a corresponding improvement in dynamic range because the emitter resistances do not increase the noise significantly at low input voltage levels. In one embodiment, a separate resistor is connected in series with the emitter of each of the four doublet transistors. Another embodiment utilizes only a single bias current source and two emitter resistors to achieve better linearity and lower noise. To achieve higher effective emitter area ratios, an emitter follower scheme can be used to synthesize all or a portion of the area ratio.

Abstract: A biasing scheme for a multi-tanh amplifier improves the dynamic range of the amplifier by utilizing emitter degeneration resistors to reduce uncorrelated noise contributed by current source transistors used to bias the multi-tanh core. The current source transistors form part of a current mirror which can be coupled to a linear-in-dB cell through another current mirror to provide linear-in-dB gain control. An optimal version of the biasing scheme for a multi-tanh triplet minimizes noise at high gain while maximizing linearity and input signal range at low gain by varying both the absolute and relative magnitudes of the bias currents for the triplet core, thereby varying the shape of the transconductance function. The variable bias currents are provided by a multiple output current mirror in which the emitter of the center mirror transistor is connected directly to power supply ground, while the outer mirror transistors include degeneration resistors in their emitter paths.

Abstract: An analog multiplier includes a new circuit topology, which includes coupling an amplifier between the collector of one of the input transistors and the bases of the other two input transistors. The amplifier used in the new topology is a double emitter-follower. The collector currents in the other two input transistors are "forced" using the conventional topology but by a simple two transistor forcing circuit comprising a Darlington emitter-follower pair rather than the conventional operational amplifier. The simple forcing circuits allow the multiplier to be used in very low voltage applications having only a single supply voltage. Voltage to current converters can be used on the front end to convert voltage input signals to current input signals, which are then provided to the analog multiplier. The voltage to current converter uses a pre-biasing scheme to produce a linear relationship between the input voltages and the input currents across the entire voltage range of the input voltages.

Abstract: A drive circuit for an oscillator having an LC tank reduces phase noise by maximizing the oscillation amplitude and minimizing the drive to the tank. The drive circuit utilizes a capacitive attenuator network for level shifting the oscillation signal before feeding it back to the drive transistors in the drive circuit, thereby allowing a large peak voltage swing across the tank without saturating the transistors. An adaptive control circuit controls the biasing of the drive transistors and reduces the drive to the tank when the maximum oscillation amplitude is reached so that the drive circuit replenishes just the minimum amount of energy lost in the tank during each cycle, thereby minimizing the coupling of active circuit noise into the tank.

Abstract: An operational amplifier connected in a voltage follwer configuration includes a variable current source in the input stage to vary the transconductance of the differential pair of transistors that form the input stage of the op-amp. A first filter pole is formed by the transconductance of the differential pair of transistors and the capacitance of a compensation capacitor used to internally compensate the op-amp. A pair of cascode transistors are connected in series with the differential pair of transistors and a cascode capacitor is coupled between the pair of cascode transistors so that a second filter pole is formed having a corner frequency that is a function of the transconductance of the pair of cascode transistors and the capacitance of the cascode capacitor. This second pole tracks with the first pole because the same current flows through the cascode transistors as through the differential pair of transistors.

Abstract: A quadrature oscillator based on two cross-coupled gm/C cells utilizes the inherent nonlinearity of positive and negative impedance cells to control the amplitude of oscillation, thereby simplifying the oscillator and eliminating the need for an outer control loop. The oscillator includes a pair of cross-coupled gm/C stages. A negative impedance cell is coupled to each gm/C cell for assuring proper start-up and enhancing the amplitude of oscillation. A positive impedance cell is also coupled to each gm/C cell to dampen the amplitude of oscillation. The transconductance of each impedance cell varies in response to the bias current provided to the cell. Thus, by controlling the bias currents through the cells, the negative and positive impedances seen by each gm/C cell can made to cancel at the desired oscillation amplitude, so that the circuit oscillates without any damping or enhancement.

Abstract: A cubic-type function generator combines the outputs from three differential pairs of transistors to generate an output current that varies in a cubic-type manner in response to the input voltage. The input offset voltages of the three differential pairs are set to different values so that the center of the hyperbolic tangent function for each differential pair is shifted along the input axis. By combining the outputs from the three differential pairs out of phase, the separate tanh functions combine to form an output function having an S-shaped curve. The amplitude of the output curve can be adjusted by varying the absolute magnitude of the bias currents to the differential pairs. The tilt and output offset can be adjusted by varying the relative magnitude of the bias currents. By driving the differential pairs with a differential voltage signal that varies as a function of temperature, the present invention generates a cubic-type temperature function.

Abstract: A crystal oscillator drive circuit controls the maximum amplitude of the drive signal to a crystal by limiting the bias current of a gm cell which senses the oscillation amplitude of the crystal. The bias current is commutated by the gm cell responsive to the crystal oscillation. The commuted current is converted to a single-ended current by a current mirror. An output stage converts the current to an output voltage having a voltage swing that is determined by the resistance of a load resistor. The output voltage is then fed back to drive the crystal through a positive feedback path. The output voltage swing and the drive signal to the crystal are limited by the bias current of the gm cell. A fully complementary implementation of the drive circuit includes two complementary gm cells, two current mirrors, and an output stage having two load resistors.

Abstract: A stator component is described which comprises first and second limbs defining respective pole faces. Each limb includes an outer surface which is provided with a pair of elongate recesses, each extending in a direction angled to the pole faces. The recesses conveniently intersect one another, and are conveniently formed using a plunge cutting technique.

Abstract: A charge pump in a phase locked loop is enabled only when a loop filter needs to be updated, thereby reducing the power consumption of the charge pump. The charge pump is enabled or disabled in response to an enable signal which is generated by a latch. The enable signal is activated by look-ahead signals which are activated in advance of either a pulse from a reference signal or a pulse from a variable signal so as to allow the charge pump to stabilize before providing the charge current to update the loop filter. Logic signals from a programmable divider and reference signal generator are used to generate the look-ahead signals. The charge pump is disabled by a reset signal from a phase-frequency detector after the loop filter is updated. The charge pump includes a current switch for generating source and sink charge currents in response to pump-up and pump-down control signals. A bias cell provides two reference signals to the current switch.

Abstract: A mixer includes a doubly-balanced mixer core, an RF input section coupled to the mixer core, and a biasing circuit coupled to the RF input section. The RF input section includes a first transistor coupled to a first input of the mixer core for supplying a first current thereto. The base of the first transistor is driven by an RF input current, as a result, the first current is responsive to the RF input current. The RF input section also includes a current mirror coupled to the first transistor, which mirrors the sum of the first current and the RF input current to produce a second current that is complementary to the first current for small variations of the RF input current. The current mirror is coupled to a second input of the mixer core to supply the second current thereto. A biasing circuit is coupled to the RF input section to establish a quiescent value of the first current. Padding resistor can also be used in the RF input section to provide a predetermined input impedance to the RF input current.