KR20230003761A - Transimpedance amplifier extending bandwidth and optical receiver comprising the same - Google Patents

Abstract

Disclosed are a transimpedance amplifier for extending a bandwidth to have a high bandwidth while resolving the problem of degraded signal quality caused by a group delay and greatly increased chip prices, and an optical receiver including the same. According to the present invention, the transimpedance amplifier comprises: a feedback transimpedance amplification terminal receiving an optical signal from a light-receiving device, converting a current signal of the inputted optical signal into a voltage signal, and amplifying the converted voltage signal; a feedback dummy amplification terminal receiving the same parasitic capacitance as the light-receiving device; a negative transconductance cell connecting gate terminals and drain terminals of two NMOSs in a cross-coupled structure to generate negative transconductance proportional to a differential pair of DC current levels, and connecting the generated negative transconductance to output nodes of the feedback dummy amplification terminal and the feedback transimpedance amplification terminal; and a negative capacitance cell connecting gate terminals and drain terminals of two NMOSs in a cross-coupled structure, connecting a capacitor to source terminals of two NMOSs, generating negative capacitance proportional to the capacitance of a capacitor and a DC current source connected to each NMOS, and connecting the generated negative capacitance to the output nodes of the feedback dummy amplification terminal and the feedback transimpedance amplification terminal.

Description

Transimpedance amplifier extending bandwidth and optical receiver comprising the same}

The present invention relates to an optical transmission/reception technology, and more particularly, to a transimpedance amplifier that improves bandwidth by using a negative transconductance stage (Negative-Gm stage) and a negative capacitance stage (Negative-C stage) and extends the bandwidth, and the same. It relates to an optical receiver comprising

A transimpedance amplifier is a photodetector that converts an optical signal into a current signal, and plays a role in converting a current signal into a voltage signal at the output stage. Since the transimpedance amplifier is located at the first input terminal of the optical receiver, it is an important block that influences the noise characteristics of the optical receiver and the entire optical transmission system. The noise characteristics of optical transmission systems determine the transmission distance of optical communication and are very important performance indicators that can limit major characteristics such as power consumption and transmission speed. Therefore, in addition to high current-voltage conversion gain (Transimpedance Gain, TZ Gain), wide bandwidth and low noise characteristics are required.

A conventional transimpedance amplifier uses an active inductor circuit technique capable of implementing an on-chip inductor and an inductance component in order to implement a higher speed than a semiconductor process. The inductor is a technology that can directly improve the bandwidth because it can cancel the parasitic capacitor component of each node that limits the bandwidth of the transimpedance amplifier, but it has some problems.

First, the bandwidth extension method by inductive peaking causes peaking compared to the mid-band in the frequency domain. Due to the rapid response change according to the frequency, the rapid cause change This means that the difference in delay time increases according to the transition pattern of input random digital data, which causes pulse dispersion and degrades signal quality.

Second, inductors are expensive to implement inside semiconductors. The inductor has a large footprint and thus occupies a large chip area, and the use of an RF process is forced to implement an inductor having a high efficiency (Q value). In addition, there is a disadvantage in that large costs are accompanied by an increase in the number of masks during mass production.

Korean Registered Patent Publication No. 10-1054388 (2011.08.04.)

A technical problem to be achieved by the present invention is to provide a transimpedance amplifier having a high bandwidth and extending a bandwidth while solving the problem of signal quality deterioration and significant increase in chip price due to group delay, and an optical receiver including the same. .

In order to achieve the above object, the transimpedance amplifier for extending the bandwidth according to the present invention receives an optical signal from a light receiving device, converts a current signal of the input optical signal into a voltage signal, and amplifies the converted voltage signal. A transimpedance amplification stage, a feedback dummy amplification stage that receives the same parasitic capacitance as the light receiving device, and a negative transconductance proportional to the DC current size of the differential pair by connecting two NMOS gate and drain stages in a cross-coupled structure. and a negative transconductance cell connecting the generated negative transconductance to output nodes of the feedback transimpedance amplification stage and the feedback dummy amplification stage and connecting two NMOS gate and drain stages in a cross-coupled structure, A capacitor is connected to the NMOS source terminal, a DC current source connected to each NMOS and a negative capacitance proportional to the size of the capacitor is generated, and the generated negative capacitance is applied to the output node of the feedback transimpedance amplification stage and the feedback dummy amplification stage. It includes a negative capacitance cell to connect.

In addition, the feedback transimpedance amplification stage and the feedback dummy amplification stage are characterized in that they are formed of a differential structure.

In addition, the feedback transimpedance amplification stage is characterized in that it has a structure in which a single-ended signal is input.

In addition, the negative transconductance cell is characterized in that the generated negative transconductance is connected in parallel to output nodes of the feedback transimpedance amplification stage and the feedback dummy amplification stage to cancel out a resistance component limiting the bandwidth of the output stage.

In addition, the negative capacitance cell is characterized in that a capacitor is connected in parallel to the two NMOS source terminals.

In addition, the negative capacitance cell is characterized in that the generated negative capacitance is connected in parallel to output nodes of the feedback transimpedance amplification stage and the feedback dummy amplification stage to cancel a capacitance component limiting the bandwidth of the output stage.

An optical receiver including a transimpedance amplifier for extending a bandwidth according to the present invention includes a transimpedance amplifier for amplifying an optical signal, an equalizer for compensating for the bandwidth of the amplified optical signal, and amplifying the compensated optical signal to enable signal processing. A limiting amplifier that restores data included in an optical signal using a clock and a data restoration circuit, wherein the transimpedance amplifier receives an optical signal from a light receiving element and generates a current signal of the input optical signal. A feedback transimpedance amplification stage that converts into a voltage signal and amplifies the converted voltage signal, a feedback dummy amplification stage that receives the same parasitic capacitance as the light receiving element, and a cross-coupled structure of two NMOS gate and drain stages A negative transconductance cell and two NMOS which generate negative transconductance proportional to the magnitude of the DC current of the differential pair and connect the generated negative transconductance to the output nodes of the feedback transimpedance amplification stage and the feedback dummy amplification stage. A gate terminal and a drain terminal are connected in a cross-coupling structure, a capacitor is connected to two NMOS source terminals, a DC current source connected to each NMOS and a negative capacitance proportional to the size of the capacitor are generated, and the generated negative capacitance and a negative capacitance cell connecting the output node of the feedback transimpedance amplifier stage and the feedback dummy amplifier stage.

In addition, it is characterized in that it further comprises a switch multiplexer for controlling the bypass (bypass) of the clock and data recovery circuit according to the necessity of the clock and data recovery circuit.

The method for extending the bandwidth of a transimpedance amplifier and an optical receiver using the same according to the present invention can solve the problem of deterioration in signal quality and significant increase in chip price due to group delay by using a negative transconductance stage and a negative capacitance stage.

In addition, it is possible to implement an optical receiver with up to twice the bandwidth of the transimpedance amplifier, and to secure a wide range of applications ranging from image transmission, datacom, computercom, and telecom.

1 is a schematic diagram for explaining a transimpedance amplifier according to an embodiment of the present invention.
FIG. 2 is a diagram for explaining the trans impedance of FIG. 1 .
FIG. 3 is a diagram for explaining an optical receiver including the transimpedance of FIG. 1 .

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function is obvious to those skilled in the art or may obscure the gist of the present invention, the detailed description will be omitted.

1 is a schematic diagram for explaining a transimpedance amplifier according to an embodiment of the present invention, and FIG. 2 is a diagram for explaining the transimpedance of FIG. 1 .

Referring to FIGS. 1 and 2 , the transimpedance amplifier 100 has a high bandwidth while solving problems of signal quality deterioration due to group delay and significant increase in chip price. The transimpedance amplifier 100 includes a feedback transimpedance amplifier stage 10, a feedback dummy amplifier stage 30 and a negative transconductance cell (Negative-Gm Stage) 50 and a negative capacitance cell (Nagativ-C Stage) 70 includes

The feedback transimpedance amplifying stage 10 receives an optical signal from the light receiving element 11 and converts a current signal of the input optical signal into a voltage signal. Here, the feedback transimpedance amplifier 10 has a structure in which a single-ended signal is input. The feedback transimpedance amplifier 10 amplifies the converted voltage signal. Here, the feedback transimpedance amplification stage 10 can be implemented as an inverter type, and can also be generally implemented as a common-source method. In addition, the feedback transimpedance amplification stage 10 may use a unity-gain current buffer having a low input impedance when a low-cost light-receiving element having a large parasitic capacitance is used.

The feedback dummy amplifier stage 30 receives the same parasitic capacitance as the light receiving element 11 . The feedback dummy amplification stage 30 does not actually receive an optical signal through the capacitor 31 acting as a dummy, and is used for differential mode operation of an equalizer or limiting amplifier of an output stage. That is, the feedback dummy amplifying stage 30 may be implemented to have a differential structure with the feedback transimpedance amplifying stage 10.

The negative transconductance cell 50 is proportional to the magnitude of the DC current of the differential pair by connecting the gate end and drain end of the first NMOS 51 and the second NMOS 53, which are two NMOS, in a cross-coupled structure. creates a negative transconductance that The negative transconductance cell 50 connects the generated negative transconductance to the output nodes of the feedback transimpedance amplifier stage 10 and the feedback dummy amplifier stage 30. At this time, the negative transconductance cell 50 connects the generated negative transconductance to the output nodes of the feedback transimpedance amplification stage 10 and the feedback dummy amplification stage 30 in parallel to cancel the resistance component that limits the bandwidth of the output stage, thereby reducing the bandwidth. can be expanded.

The negative capacitance cell 70 connects the gate end and the drain end of two NMOSs, the third NMOS 71 and the fourth NMOS 73, in a cross-coupled structure, and the third NMOS 71 and the fourth NMOS 73 are connected. A capacitor 75 is connected to the source terminal. The negative capacitance cell 70 generates a negative capacitance proportional to the size of the DC current sources 77 and 79 and the capacitor 75 connected to the NMOSs 71 and 73 respectively. The negative capacitance cell 70 connects the generated negative capacitance to output nodes of the feedback transimpedance amplification stage 10 and the feedback dummy amplification stage 30 . At this time, the negative capacitance cell 70 connects the generated negative capacitance to the output nodes of the feedback transimpedance amplifier stage 10 and the feedback dummy amplifier stage 30 in parallel to cancel the capacitance component that limits the bandwidth of the output stage, thereby extending the bandwidth. can do.

As described above, the transimpedance amplifier 100 of the present invention can extend the bandwidth by using the negative transconductance cell 50 and the negative capacitance cell 70. In particular, since the transimpedance amplifier 100 has an inductor type structure, it can be free from a voltage headroom problem.

FIG. 3 is a diagram for explaining an optical receiver including the transimpedance of FIG. 1 .

Referring to FIGS. 1 to 3 , the optical receiver 200 can be implemented to reach a maximum of twice the bandwidth of the transimpedance amplifier. In addition, the optical receiver 200 can secure a wide range of applications ranging from image transmission, datacom, computercom, and telecom. The optical receiver 200 includes a transimpedance amplifier 100, an equalizer 210, a limiting amplifier 220, and a clock and data recovery circuit 240, and may further include a switch multiplexer 240.

The transimpedance amplifier 100 receives an optical signal, which is a single-ended signal, and amplifies the input optical signal. At this time, the transimpedance amplifier 100 can extend the bandwidth by using the negative transconductance cell 10 generating negative transconductance and the negative capacitance cell 30 generating negative capacitance as described above.

The equalizer 210 is connected to an output terminal of the transimpedance amplifier 100 and compensates for a bandwidth of an optical signal amplified by the transimpedance amplifier 100 . That is, the equalizer 210 can further compensate for the bandwidth by improving the frequency characteristics of the optical signal. In this case, the equalizer 210 may be a linear equalizer.

The limiting amplifier 220 is connected to the output terminal of the equalizer 210 and amplifies the optical signal compensated from the equalizer 210 to enable signal processing. At this time, the limiting amplifier 220 can control the amplification so that it does not exceed a preset standard.

The clock and data restoration circuit 240 is connected to the output terminal of the limiting amplifier 200 and restores data included in the optical signal using a clock. The clock and data recovery circuit 240 resamples the data included in the optical signal based on a preset clock to accurately reconstruct the data in time.

The switch multiplexer 240 is connected to an output terminal of the clock and data recovery circuit 240 and controls bypass of the clock and data recovery circuit 240 depending on whether or not the clock and data recovery circuit 240 is needed. That is, there are cases where the clock and data recovery circuit 240 is required depending on circumstances, but there are also cases where it is not necessary. can pass

Meanwhile, as shown in FIG. 3 , the optical receiver 200 may include a register, a DC-offset cancellation circuit, etc. in addition to the above-described configuration, and since a description of the corresponding configuration is well-known, no further description will be made.

Although the above has been described and illustrated in relation to preferred embodiments for illustrating the technical idea of the present invention, the present invention is not limited to the configuration and operation as shown and described in this way, without departing from the scope of the technical idea. It will be readily apparent to those skilled in the art that many changes and modifications can be made to the present invention. Accordingly, all such appropriate changes and modifications and equivalents should be regarded as falling within the scope of the present invention.

10: feedback transimpedance amplification stage
30: feedback dummy amplification stage
50: negative transconductance cell
70: negative capacitance cell
100: transimpedance amplifier
200: optical receiver
210: equalizer
220: limiting amplifier
230: clock and data recovery circuit
240: switch multiplexer

Claims (8)

a feedback transimpedance amplifying stage that receives an optical signal from a light receiving element, converts a current signal of the input optical signal into a voltage signal, and amplifies the converted voltage signal;
a feedback dummy amplifier receiving the same parasitic capacitance as the light receiving element;
The two NMOS gate and drain terminals are connected in a cross-coupled structure to generate negative transconductance proportional to the magnitude of the DC current of the differential pair, and the generated negative transconductance is transferred to the feedback transimpedance amplifying stage and the a negative transconductance cell connected to the output node of the feedback dummy amplification stage; and
Connecting two NMOS gate terminals and drain terminals in a cross-coupled structure, connecting capacitors to the two NMOS source terminals, generating a DC current source connected to each NMOS and a negative capacitance proportional to the size of the capacitor, a negative capacitance cell connecting the negative capacitance to the output nodes of the feedback transimpedance amplification stage and the feedback dummy amplification stage;
A transimpedance amplifier that extends the bandwidth including a. According to claim 1,
The transimpedance amplifier that extends the bandwidth, characterized in that the feedback transimpedance amplifier stage and the feedback dummy amplifier stage are formed of a differential structure. According to claim 1,
The feedback transimpedance amplifier stage,
A transimpedance amplifier that extends the bandwidth, characterized in that it has a structure in which a single-ended signal is input. According to claim 1,
The negative transconductance cell,
and connecting the generated negative transconductance to output nodes of the feedback transimpedance amplifier stage and the feedback dummy amplifier stage in parallel to cancel out a resistance component limiting the bandwidth of the output stage. According to claim 1,
The negative capacitance cell,
A transimpedance amplifier that extends the bandwidth, characterized in that a capacitor is connected in parallel to the two NMOS source terminals. According to claim 1,
The negative capacitance cell,
The bandwidth extending transimpedance amplifier, characterized in that the generated negative capacitance is connected in parallel to output nodes of the feedback transimpedance amplification stage and the feedback dummy amplification stage to cancel the capacitance component limiting the bandwidth of the output stage. a transimpedance amplifier that amplifies the optical signal;
an equalizer compensating for a bandwidth of the amplified optical signal;
a limiting amplifier for amplifying the compensated optical signal to enable signal processing;
A clock and data recovery circuit for restoring data included in the optical signal using the clock;
The transimpedance amplifier,
a feedback transimpedance amplifying stage that receives an optical signal from a light receiving element, converts a current signal of the input optical signal into a voltage signal, and amplifies the converted voltage signal;
a feedback dummy amplifier receiving the same parasitic capacitance as the light receiving element;
The two NMOS gate and drain terminals are connected in a cross-coupled structure to generate negative transconductance proportional to the magnitude of the DC current of the differential pair, and the generated negative transconductance is transferred to the feedback transimpedance amplifying stage and the a negative transconductance cell connected to the output node of the feedback dummy amplification stage; and
Connecting two NMOS gate terminals and drain terminals in a cross-coupled structure, connecting capacitors to the two NMOS source terminals, generating a DC current source connected to each NMOS and a negative capacitance proportional to the size of the capacitor, a negative capacitance cell connecting the negative capacitance to the output nodes of the feedback transimpedance amplification stage and the feedback dummy amplification stage;
An optical receiver comprising a transimpedance amplifier that extends the bandwidth, characterized in that it comprises a. According to claim 7,
a switch multiplexer controlling bypass of the clock and data recovery circuits according to whether the clock and data recovery circuits are necessary;
An optical receiver comprising a transimpedance amplifier that extends the bandwidth, further comprising a.

Images