1. Field of the Invention
The present invention relates generally to a switched-current resistor (SCR) programmable gain array (PGA) targeted for wireless local area network (WLAN) applications. More specifically, embodiments of the present invention relate to an SCR PGA, where an SCR array may be employed in parallel with a feedback resistor to achieve constant bandwidth transient-free gain control.
2. Background Art
The rapid evolution of CMOS technology has accelerated the integration of mixed-signal systems, such as the wireless transceiver on a single chip. In the case of a zero intermediate-frequency (IF) or low IF receiver architecture targeted toward IEEE 802.11 a/b/g WLAN applications, signal levels arriving at the baseband are scaled to around a 0 dBm range for analog-to-digital conversion. With technology scaling, capacitive coupling in a zero IF receiver would increase enough to contribute to the de-offset problem. The dc-offset problem may be mitigated through the employment of a low-IF receiver, which also allows for increased integration. However, appropriate design of constituent circuits is vital under low voltage (LV) constraints.
The dynamic-range requirement from the antenna (input terminal 105) to the baseband may approximately equal 0 to 80 dB, with the majority of the gain achieved in the baseband. If the radio front-end offers a 0 to 30 dB range, the baseband channel selection filters 130 and 135, along with the PGAs 140 and 145 have to offer another 0 to 50 dB of controllable gain. Although cascading multiple PGAs may lead to such high gain ranges, excess bandwidths are required of the PGAs, sometimes equal to ten times the bandwidth of the channel-selection filters, to ensure stable selectivity against gain.
Technology scaling within submicron scales, when accompanied with a standard power supply, may not necessitate a significant change in the design of analog blocks.
One way to render an inverting amplifier 250 suitable for a minimum drain supply voltage (VDD) is to use a level shifter. As shown in
VDD>|VT,p+|2VSDsat+2VDSsat, (1)
where VT,p is the p-channel transistor threshold voltage, and VSDsat is the source-drain saturation voltage.
For a VT,p of −0.65 V, the lowest possible VDD is approximately 1V. The output 254 stage of the inverting amplifier 250 may be a typical class-A amplifier 254 (see
VOD=VDD−VT,n−VDS,sat, (2)
where VT,n is the n-channel transistor threshold voltage.
Additionally, two distinct reference voltages, Vref,in 272 of 0.1 V and Vref,out 285 of 0.5 V may be required (see
According to one aspect of one or more embodiments of the present invention, an SCR PGA for constant bandwidth gain control includes an inverting amplifier, a feedback resistor forming a feedback loop between an output side and an input side of the inverting amplifier, and an SCR array connected in parallel to the feedback resistor, and configured to tune a gain range between a maximum and a minimum. The SCR array includes a plurality of switched resistors, each comprising a switch in series with a resistor. A constituent switched resistor of the plurality of switched resistors is connected to another switched resistor in parallel. When the plurality of switched resistors are switched by a gain-control logic, a plurality of switched current sources and a plurality of grounded resistors are switched correspondingly such that the plurality of switched current sources deliver a transient current, an equivalent of which flows through the plurality of grounded resistors out from the input side of the inverting amplifier, leading to a feedback factor of the PGA being constant.
According to one aspect of one or more embodiments of the present invention, a receiver for use in wireless local area networks includes a low noise amplifier, a first mixer with a first local oscillator reference frequency in an RF range, a second mixer with a second local oscillator reference frequency in an IF range, a channel selection filter, and an SCR PGA. The SCR PGA includes an inverting amplifier, a feedback resistor forming a feedback loop between an output side and an input side of the inverting amplifier, and an SCR array connected in parallel to the feedback resistor and configured to tune a gain range between a maximum and a minimum. The SCR array includes a plurality of switched resistors, each comprising a switch in series with a resistor. A constituent switched resistor of the plurality of switched resistors is connected to another switched resistor in parallel. When the plurality of switched resistors are switched by a gain-control logic, a plurality of switched current sources and a plurality of grounded resistors are switched correspondingly such that the plurality of switched current sources deliver a transient current, an equivalent of which flows through the plurality of grounded resistors out from the input side of the inverting amplifier, leading to a feedback factor of the PGA being constant.
According to one aspect of one or more embodiments of the present invention, a method for realizing a constant bandwidth transient-free gain control in a PGA includes connecting a feedback resistor across an input side and an output side of the inverting amplifier, connecting an SCR array in parallel to the feedback resistor, the SCR array being configured to tune a gain range between a maximum and a minimum and including a plurality of switched resistors, each comprising a switch in series with a resistor, and switching the plurality of switched resistors by a gain-control logic such that a plurality of switched current sources and a plurality of grounded resistors are switched correspondingly to deliver a transient current, an equivalent of which flows through the plurality of grounded resistors out from the input side of the inverting amplifier, leading to a feedback factor of the PGA being constant. A constituent switch resistor of the plurality of switched resistors is connected to another switched resistor in parallel.
Other aspects and advantages of the invention will be apparent from the following description and the appended claims.
a) shows a typical low voltage (LV) switched-resistor PGA circuit.
b) shows the input and output stages of the inverting amplifier of the PGA 200.
Although the aforereferenced PGA structure of
These unequal common-model levels and the associated gain-dependent dc current may entail a long settling time to re-stabilize the input-output (I/O) CMFBs and the opamp at a new quiescent operating point.
Specific embodiments of the invention will now be described in detail with reference to the accompanying figures. Like elements in the various figures are denoted by like reference numerals for consistency.
In the following detailed description of embodiments of the invention, numerous specific details are set forth in order to provide a more thorough understanding of the invention. However, it will be apparent to one of ordinary skill in the art that the invention may be practiced without these specific details. In other instances, well-known features have not been described in detail to avoid unnecessarily complicating the description.
In general, embodiments of the present invention describe an SCR PGA that provides for gain-independent output bandwidths, sinks out the unwanted gain-dependent dc current, and dispels the need for buffers. In one or more embodiments, such an SCR PGA may be operational underneath a very low-voltage (LV) VDD of 1V or less. For simplicity sake, a VDD of 1V is assumed in the detailed description below. One of ordinary skill in the art will recognize that other VDD values may be used in accordance with one or more embodiments of the present invention.
In one or more embodiments, a set of switched resistors 322,1 to 322,n (i.e. Rfb,1 . . . Rfb,n) may be added in parallel with Rfb 320 to achieve a tunable gain range between a maximum of
and a minimum of
In one embodiment, when 322,1 . . . 322,n (Rfb,1 . . . Rfb,n) are switched by the gain-control logic 323,1 . . . 323,n (bc,1 . . . bc,n) of the switches in the SCR bank, a set of switched current sources 326,1 . . . 326,n (Ifb,1 . . . Ifb,n) and grounded resistors 324,1 . . . 324,n (Rx,1 . . . Rx,n) may be switched correspondingly such that 326,1 . . . 326,n (Ifb,1 . . . Ifb,n) may replace the opamp to deliver the transient current, while 324,1 . . . 324,n (Rx,1 . . . Rx,n) may sink the same current out from Vvg− as given by:
In one or more embodiments, equalizing the last two terms of Equation (4) over process, voltage, and temperature (PVT) variation is not complicated because Vcm,out and Vcm,in (see
In one embodiment, Vz may be a mirror of Vx that may be set to 0.1 V (VDD/10), thereby enabling Aerror 425 to be realized via a p-channel differential pair. Resistors 405, 410, 415 are resistors R1, R2, R4 respectively, and transistor 430 is a dummy transistor Md. Ifb,ref may be mirrored afterward to the switched current sources I′fb,1 . . . I′fb,n through transistors M1 435 to Mb,1, . . . Mb,n, which may feature the same ratios of Rfb,1 to Rfb,1 . . . Rfb,n. I′fb,n may be related to the normalized Rfb,1 through example Equation (5) as:
Making I′fb,n proportional to just
may be done by substituting R3 420 with
This may equalize the numerator of Equation (5) to the second term of Equation (4), (i.e., 4Vz=Vcm,out−Vcm,in), resulting in example Equation (6)
Substituting Equation (6) back into the first term of Equation (4), and replacing Rfb,n and Rx,n in accordance with αnRu=Rfb,n=4Rx,n may lead to example Equation (7) as:
In one or more embodiments, as Vz, Vcm,out, and Vcm,in (see
In one or more embodiments, as seen from example Equation (8), the R-to-I conversion circuit may yield an overall PVT-insensitive operation, whose employment may further the static and dynamic performances of the SCR PGA.
In one or more embodiments, the current mirror M1 to Mb,1 . . . Mb,n may raise the precision by adding
thereby level shifting the drain voltage VD of M1 to match that of Mb,1 . . . Mb,n.
In one or more embodiments, the overall resistor matching, and the ground-noise rejection of Aerror 425 and Aref 440 may be enhanced by selecting, for example,
thereby resulting in a resistor spread of just 9. Here, Aref 440 may form a non-inverting amplifier for buffering Vref,out. In
In one or more embodiments, I′fb,1 . . . I′fb,n may be switched through transistors Ms,1 . . . Ms,n rather than Mb,1 . . . Mb,n such that Ms,1 . . . Ms,n may attain the maximum overdrive voltage, leading to reduced device sizes and lower charge injection values. In one embodiment, as only the current paths are opened, the gate-to-source capacitance of Mb,1 . . . Mb,n may be kept charged for a faster turn-on time.
In one or more embodiments, connecting Mb,1 . . . Mb,n to VDD may prevent charge injection of Ms,1 . . . Ms,n from coupling to the gates thereof through a body-to-gate parasitic capacitance thereof, thereby theoretically yielding 200% to 300% shorter transients depending on the gain step.
In one or more embodiments, the feedback factor βPGA may be expressed as example Equation (9):
In one or more embodiments, βPGA may be stabilized when the two conditions ((10) and (11)) specified below are satisfied concurrently.
As conditions (10) and (11) depend on relative ratio rather than absolute values, βPGA may be robustly stabilized against gain over PVT. Advantages of a constant βPGA may include unvarying settling time and constant stopband rejection.
In one or more embodiments, the constancy of PGA may practically depend on the ratio of resistances of Rcm,in to Rff of and Rx,1 . . . Rx,n. Even with a large Rcm,in in comparison to Rff∥Rx,1 . . . ∥Rx,n, βPGA may only vary in very small quantities, leading to only a small bandwidth variation. In one or more embodiments, identical PGAs may be cascaded to attain required gain range. Although identical cascaded PGAs reduce bandwidth, which is multiplied by a factor of
(N being the number of cascaded stages), a large βPGA may result in a net bandwidth enlargement, with an obvious increase in power due to increase in the number of PGAs.
It will be obvious to one of ordinary skill in the art that the abovementioned SCR circuit details, transistor types and choices, R-to-I conversion circuit elements, R-to-I conversion choice parameters, input and output sections of the SCR PGA all are explained for clarity purposes and any variations in them would not depart from the scope of the invention. Modifications in the aforementioned are well within the scope of the invention.
In one or more embodiments, dc-offset cancellation may be incorporated for a fully differential circuit implementation, whereby the even-harmonic distortion may be suppressed effectively such that only the odd harmonics are dominant. In one embodiment, an example determination of the third-harmonic distortion (HD3) of a highly linear resistor in series with a nonlinear n-MOS switch would require an assumption of reception of the sinusoidal signal by the terminal in the resistor side, with the terminal in the switch side being grounded. HD3 may then be expressed in the form of example Equation (12) as:
where Vg is the transistor gate voltage, Vout−,p is the peak value of the output voltage, and ron is the transistor on-resistance. For example, for a HD3 of a very low level, ron may be a small fraction, albeit sizeable, of Rfb. This indicates that explicitly biasing Vcm,in to a value close to one of the supply rails may help improve the linearity due to an increase in VOD.
In one or more embodiments, the squared output thermal noise of the PGA may be lowered by keeping the resistor spread small and increasing the level of Vcm,in.
As discussed above, one or more embodiments of the SCR PGA offers advantages, not limited to a stable feedback factor, transient-free gain control, and elimination of loading effects in a multi-stage PGA. In one or more embodiments, stable selectivity against gain is ensured as the bandwidth requirement of the PGA may be relaxed. In one such embodiment, the bandwidth requirement of the PGA may be relaxed to less than 20 MHz. In one or more embodiments, reduction of the settling times in gain change may be achieved, and one or more embodiments may offer enhanced stopband rejection.
While the invention has been described with respect to an exemplary embodiment of an SCR PGA for achieving a constant bandwidth transient-free gain control, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. Accordingly, the scope of the invention should be limited only by the attached claims.