This invention relates to programmable logic devices (“PLDs”) and other integrated circuits of that general type (all generically referred to for convenience as PLDs). More particularly, the invention relates to high-speed serial data transmitter circuitry for inclusion on PLDs.
PLDs are intended as relatively general-purpose devices. A PLD can be programmed (configured) to meet any need within the range of needs that the PLD is designed to support. A PLD may be equipped with high-speed serial data communication circuitry, whereby the PLD can transmit serial data to and/or receive serial data from circuitry that is external to the PLD. In that case, it is desirable for the high-speed serial data communication circuitry of the PLD to be able to support various communication protocols that various users of the PLD product may wish to employ. It is also desirable for the PLD's high-speed serial data communication circuitry to be able to perform successfully in various circuit or system contexts. This invention provides high-speed serial data transmitter circuitry that can be configured to meet a wide range of possible needs.
In accordance with the invention, serial data transmitter circuitry on a PLD may include such features as (1) multiple pre-emphasis circuits of selectable strength and polarity, (2) selectable VOD (differential output voltage), (3) selectable slew rate (steepness of transitions in the transmitter output signals), (4) calibratable termination resistor circuitry, (5) selectable common mode voltage, and/or (6) an electrical idle mode of operation. These various features may be programmably controlled (e.g., from programmable configuration random access memory (“CRAM”) cells on the PLD) and/or more dynamically controlled (e.g., from user-mode signals on the PLD). The control may involve selective enablement or disablement of a feature and/or selection of an operating characteristic or parameter for the feature.
Further features of the invention, its nature and various advantages, will be more apparent from the accompanying drawings and the following detailed description.
A portion of illustrative transmitter circuitry 10 is shown in
The serial data signal to be transmitted is applied (in differential form) to the inputs of each of pre-driver circuits 40, 42, 44, and 46. Pre-driver circuitry 40 and the circuit elements 20, 30, and M1-M4 associated with that pre-driver are the “main” driver circuitry of transmitter 10. These components typically supply a major portion of the power to the differential output terminals TX_P and TX_N of the transmitter. Accordingly, the differential output signal (TX_P, TX_N) of the transmitter is intended to correspond to the serial data signal applied to main pre-driver 40. However, output signal TX_P, TX_N may additionally be given pre- and/or post-emphasis by operation of other components of the transmitter as described below. (In general, the term pre-emphasis will be used as a generic term for all forms of pre- and post-emphasis that are shown and described herein.)
As shown in
Continuing with
The output signals of each of pre-drivers 40, 42, 44, and 46 can make a contribution to the final transmitter output signal TX_P, TX_N via the associated current sources 20, 22, etc., and 30, 32, etc., and the associated transistors M. For example, elements 20, 30, and M1-M4 are associated with main pre-driver 40. Elements 20, M1, M4, and 30 are connected in series between VCC and ground. Elements M2 and M3 are connected in series with one another in parallel with elements M1 and M4. TX_N is connected to the node between M1 and M4. TX_P is connected to the node between M2 and M3. The “true” output signal of main pre-driver 40 controls turn-on and turn-off of complementary transistor M1 and M4. The “complement” output signal of main pre-driver 40 similarly controls turn-on and turn-off of complementary transistors M2 and M3. For example, M1 is off and M4 is on when the true output of pre-driver 40 is high. M1 is on and M4 is off when the true output of pre-driver 40 is low. M2 is always off when M1 is on, and vice versa. Similarly, M3 is always off when M4 is on, and vice versa. When M1 and M3 are turned on, current sources from current source 20 through M1, through resistors 50b and 50a, and sinks to current source 30 through M3. This places TX_N on the high-potential side of resistors 50, and it places TX_P on the low-potential side of those resistors. When the applied data signal reverses polarity, M2 and M4 are on and M1 and M3 are off. Accordingly, current sources from current source 20 through M2, through resistors 50a and 50b, and sinks to current source 30 through M4. TX_P and TX_N are therefore driven to reverse polarity relative to their polarity when M1 and M3 were on and M2 and M4 were off.
Each of the other pre-drivers 42, 44, and 46 have associated arrangements of current sources and transistors identical to the arrangement described above for current source 40. For example, associated with pre-tap pre-driver 42 are current sources 22 and 32 and transistors M13-M16. This arrangement of pre-tap circuit elements can make a contribution to signals TX_P and TX_N by the same means that the above-described main circuit elements can make. Of course, the contributions actually made by these two groups of circuit elements, at any given time, are typically different from one another. But whatever these contributions are, they are added together by virtue of being applied in parallel to the conductors leading to TX_P and TX_N.
Everything said in the preceding paragraph is equally applicable to the circuitry associated with 1st post pre-driver 44 (i.e., current sources 24 and 34 and transistors M5-M8). It is also equally applicable to the circuitry associated with 2nd post pre-driver 46 (i.e., current sources 26 and 36 and transistors M9-M12).
The strength of each of the above-mentioned contributions to TX_P and TX_N is controlled by the strength of the associated variable current sources 20, 22, etc., and 30, 32, etc. The strength of each current source is preferably programmably controlled, e.g., as shown in
The strength of current sources 20 and 30 controls the VOD (differential offset voltage) parameter of transmitter 10. VOD is the basic or nominal voltage difference between TX_P and TX_N during transmission of data. (Of course, the polarity of this difference reverses each time the data changes from 0 to 1 or vice versa.) In an illustrative embodiment, VOD can be selected to have any of several values in the range from 200 mv to 1400 mv. This selection is made by appropriately programming the CRAM cells 210 that control the strength of main current sources 20 and 30. The stronger these current sources are, the higher VOD is.
The strength of the other current sources controls the strength of the contribution to TX_P and TX_N from pre-tap pre-driver 42 and its associated circuitry, from 1st post pre-driver 44 and its associated circuitry, and from 2nd post pre-driver 46 and its associated circuitry. For example, the strength of current sources 22 and 32 controls the strength of the pre-emphasis contribution from circuit elements 22, 32, 42, and M13-M16. The strength of current sources 24 and 34 controls the strength of the 1st post emphasis contribution from circuit elements 24, 34, 44, and M5-M8. The strength of current sources 26 and 36 controls the strength of the 2nd post emphasis contributions from circuit elements 26, 36, 46, and M9-M12. In each case, the strength of the current sources mentioned in this paragraph may be programmably controlled in the manner generically illustrated by
Another transmitter control feature that is shown in
Still another transmitter control feature that is shown in
Although elements 50a, 50b, and 60 are shown in
Termination resistors 50a and 50b are connected in series across the leads to TX_P and TX_N. Common mode driver circuitry 60 is connected in series between the node between resistors 50 and ground.
Each of resistors 50 has variable resistance, which is selectable by signals from CRAM cells 410. For example, each of resistors 50 may have resistance that is selectable to be 50 ohms, 60 ohms, or 75 ohms, depending on the programmed state of CRAM cells 410. Accordingly, the termination resistance connected across TX_P and TX_N can be 100, 120, or 150 ohms. This feature can be used to help transmitter 10 better match the impedance of whatever external circuitry the transmitter is driving.
Common mode driver circuitry 60 is a variable voltage source. Vtt_CONTROL signals 420 can be used to control the voltage circuitry 60 maintains at its upper (positive) terminal. This is the so-called common mode voltage (“VCM”) of transmitter 10. Accordingly, the circuitry allows the VCM of transmitter 10 to be selected to have any of several possible values. Because some communication protocols may require VCM to be different at different times during operation of the PLD, Vtt_CONTROL signals 420 may come from a relatively dynamic signal source such as state machine circuitry on the PLD. Alternatively, if it desired for VCM to be selectable but not dynamically changeable, Vtt_CONTROL signals 420 may come from programmable CRAM cells on the PLD.
Some communication protocols such as PCI-Express require support for an electrical idle mode and a receiver detect capability. Receiver detect is the ability to detect the presence or absence of receiver circuitry at the other end of a communication link.
We now recapitulate the many capabilities of the transmitter architecture described above. As the industry introduces more and more communication standards to cover a vast application space, the solution provided by a programmable transceiver becomes more demanding. The data rates span from as low as 600 MBps to 6 GBps. To make it more difficult, even the bandwidth keeps increasing. To keep the cost of the system down, the interconnect materials stay the same as the previous generation(s). That translates to a degrading performance of the medium at higher frequencies, resulting in a big challenge to the transceiver design.
The present invention provides one transmitter design to meet the different electrical specifications for such parameters as VOD, termination, rise/fall time, etc. This transmitter design satisfies a wide range of signal integrity requirements. For example, this transmitter architecture can be used to send signals through mediums that have frequency-dependent characteristics as shown in the balloon above communication link 610 in
The transmitter driver architecture of this invention employs the following features to enhance performance and power. First, the architecture employs H-tree driver circuitry for high performance, coupled with efficient power/area/noise reduction. (See, for example, commonly assigned, co-pending Asaduzzaman et al. U.S. patent application Ser. No. 11/192,607, filed Jul. 29, 2005.) Second, the architecture employs separation of powers for the pre-driver and driver circuitries. Note in connection with this second point that
The following controls are programmable or selectable: VOD, pre-emphasis pre-tap, two post-taps, inversion for pre-tap and second post-tap, slew-rate switch, calibration termination, and common mode driver.
With regard to VOD, the transmitter is required to produce differential output voltage for different specifications. It is capable, in an illustrative embodiment, of driving a differential peak-to-peak signal ranging from 200 mv to 1400 mv. The control bits VOD in
With regard to pre-emphasis, as the transmission system degrades at high frequency, the signal is not only attenuated but also gets distorted in shape, resulting in a setback to a quality signal arriving at its destination. To overcome these obstacles, the present transmitter is equipped with pre-emphasis resources from one pre-tap and two post-taps with different amplitudes. In an illustrative embodiment, the transmitter is targeted to drive up to 40 inches of FR4 at 6.375 Gbps. To be more flexible, the pre-tap and second post-tap polarities can be inverted. Each tap has several settings for different amounts or levels of the pre-emphasis. In
With regard to signal inversion on pre-emphasis taps, different back-planes may have different characteristics. The ability to selectively invert certain taps provides flexibility to compensate for the distortion at the far end. The control bits in
With regard to slew rate control, fast edge rates introduce high frequency components in the transmitted signal. This can result in inter-symbol interference (“ISI”) and jitter. In a back-plane where traces are highly susceptible to noise, fast edge rate can also cause functional failure. Therefore, in applications where the data rates do not require fast switching (e.g., below about 3 Gbps), the slew rate control is used to slow down the edge rates. The slew rate control signal(s) in
With regard to the common mode driver, this component (60) provides a low impedance termination path to common mode voltage. The control bits 420 in
The transmitter circuitry also has a calibration feature with on-chip termination (variable resistors 50). This can be used to absorb any reflection that bounces back from the interconnect medium, since there can be several discontinuities from the driver to the receiver (e.g., a connector). The calibration unit provides offset to the termination due to process variation. Some specifications might ask for termination different than 100 ohm differential. In
Further with regard to electrical idle, the signal TX_ELEC_IDLE in
As has been noted, receiver detect is a requirement to support PCI-Express. This circuitry is used in conjunction with the TX driver. It needs both pins in the TX driver to feed back the signals sensed from the link to see if there is a presence of the receiver at the other end. In addition, the signal TX_DETECT_RX (
In sum, transmitter design is encountering more challenges as a result of the complex nature of the requirements. The transmitter of this invention, with the described features and programmable controls, provides the solution to a wide range of applications within one product.
It will be understood that the foregoing is only illustrative of the principles of the invention, and that various modifications can be made by those skilled in the art without departing from the scope and spirit of the invention. For example, not all of the features shown and described herein need to be included in all embodiments of the invention.
This is a continuation of U.S. patent application Ser. No. 11/345,709, filed Feb. 1, 2006, now U.S. Pat. No. 7,355,449 which is hereby incorporated by reference herein in its entirety. This application claims the benefit of U.S. provisional patent application No. 60/705,690, filed Aug. 3, 2005, which is hereby incorporated by reference herein in its entirety.
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5066873 | Chan et al. | Nov 1991 | A |
6404671 | Reohr et al. | Jun 2002 | B1 |
6635934 | Hidaka | Oct 2003 | B2 |
6744287 | Mooney et al. | Jun 2004 | B2 |
7030652 | Lewis et al. | Apr 2006 | B1 |
7221193 | Wang et al. | May 2007 | B1 |
20070013411 | Asaduzzaman et al. | Jan 2007 | A1 |
Number | Date | Country | |
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60705690 | Aug 2005 | US |
Number | Date | Country | |
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Parent | 11345709 | Feb 2006 | US |
Child | 12069353 | US |