JP2002064399A - Software Defined Radio - Google Patents

Abstract

(57) [Summary] [Object] With respect to a software defined radio capable of supporting various systems, an object of the present invention is to realize a device that is small and consumes low power without requiring strict requirements for hardware. A software defined radio apparatus comprising a signal processing block and a plurality of functional blocks, wherein each of the functional blocks includes an operation parameter and a table describing characteristics of hardware constituting each of the functional blocks, A second interface for adjustment between the processing block and each functional block, wherein each of the functional blocks and the signal processing block mutually adjust based on the contents of the table via the second interface To optimize the distribution of compensation for deterioration factors caused by hardware imperfections,
By performing based on the contents of the table, the functional blocks and the signal processing blocks cooperate to realize desired characteristics.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a software defined radio apparatus capable of coping with various systems by realizing signal processing related to wireless communication by software using a processor and replacing the software.

[0002]

[Prior Art] Signal processing related to communication such as modulation and demodulation and call control is all performed by DSP (Digital Signal Plocess).
Or, a software defined radio that is realized by software on a processor such as a CPU (Central Processing Unit) or the like, and that can cope with various systems by exchanging software is being studied.

A document which discloses one of such techniques, "Software Radio Apparatus" Japanese Patent Application No. 11-214720.
Has proposed a software defined radio apparatus in which each functional block has a processor and defines an interface condition between the signal processing unit and each functional block.

The signal processing unit of the conventional software defined radio apparatus does not directly participate in the control of each function block, but sends an index of a control target to each function block. Performed by the processor on the block. By adopting such a control structure, concentration of processing load on the signal processing unit is eliminated.

FIG. 2 shows an example of the configuration of a software defined radio apparatus according to FIG. In the figure, reference numerals 10 to 15 denote main signals, 100 denotes a software defined radio, 200 denotes an antenna control unit, 210 denotes an antenna, and 250, 350 and 750 denote functional block processors.

Reference numeral 300 denotes a radio signal processing unit, 400 denotes a D / A converter, 500 denotes an A / D converter, 600 denotes a signal processing unit, 700 denotes an external interface unit, 800 denotes an external input / output terminal, and 850 denotes an external input / output terminal. Software 900 represents a control interface.

The signal processing unit 600 includes an antenna control unit 20
0, radio signal processing unit 300, external interface unit 70
The control command and the parameter are transmitted to 0 via the internal interface 900. Each of these functional blocks
Built-in processors 250, 350, 750 respectively
The processor makes necessary judgments and settings for the control commands.

The control command and parameters include the number of antennas and directivity information, the gain of a receiving amplifier, the frequency and bandwidth used, required out-of-band unnecessary wave suppression information, signal quality information, and the like. Conversely, each function block 200, 30
Reference numerals 0 and 700 denote operation state information to the signal processing unit 600, and the signal processing unit grasps the operation of each unit of the wireless device, such as the number of used antennas and frequency characteristics.

In each function block, a processor is provided, and an interface condition between the signal processing unit and each function block is defined. With respect to the control of the function block, the signal processing unit determines an index such as a control target. The signal is sent to each functional block, and each functional block eliminates the concentration of the processing load on the signal processing unit by performing individual control by the processor on each functional block.

[0010]

In the conventional software defined radio as described above, each functional block of the software defined radio is required to have the highest performance in order to meet various required specifications. . This is because the software defined radio is adapted to various specifications by rewriting software.

Further, since it is assumed that the hardware operates ideally, the strictest conditions are required for each hardware within the specifications of the system to be supported. For this reason, there has been a problem that the device scale and the power consumption inevitably increase. An object of the present invention is to realize a small-sized and low-power-consumption device without requiring strict requirements for hardware in a software defined radio device.

[0012]

According to the present invention, the above-mentioned object is solved by the means described in the claims. That is, the invention of claim 1 performs a signal processing necessary for wireless communication, and a signal processing block capable of changing its function by replacing software, an antenna unit, a wireless signal processing unit for performing frequency / level conversion, and the like, The external interface unit includes a plurality of functional blocks constituting a wireless device. Each functional block includes a signal processing device for setting its function and operation. The signal processing block and each function block are provided. Comprises a first interface for mutual information exchange, and exchanges information between the signal processing block and any of the functional blocks via the first interface;
The signal processing block recognizes an operation state of the entire wireless device from information obtained from each of the function blocks, and each of the function blocks is based on control information obtained from the signal processing block and any function block. , Necessary judgment,
A software defined radio for setting,

The function block includes a table describing operation parameters and characteristics of individual hardware constituting the function block, a second interface for adjustment between the signal processing block and each function block, The functional blocks and the signal processing blocks mutually adjust based on the contents of the table via the second interface, thereby allocating compensation for deterioration factors caused by hardware incompleteness. Optimize and
This is a software defined radio apparatus in which the function compensation signal processing is performed based on the contents of the table so that the functional blocks and the signal processing blocks cooperate to realize desired characteristics.

According to a second aspect of the present invention, there is provided a signal processing block capable of performing signal processing necessary for wireless communication and changing its function by replacing software, an antenna unit, a radio signal processing unit for performing frequency / level conversion, and the like. , An external interface unit, and a plurality of functional blocks constituting a wireless device, each functional block including a signal processing device for setting its function and operation, the signal processing block, and each function The block is provided with an interface for mutual information exchange, and exchanges information between the signal processing block and any of the functional blocks via the interface. Recognizing the operation state of the entire wireless device from the information obtained from the blocks, each of the functional blocks, the signal processing block and Based on the control information obtained from the functional blocks will, necessary decision, a software radio apparatus for setting,

Each of the functional blocks has a table describing the operating parameters and characteristics of the individual hardware constituting the functional block, and the functional blocks and the signal processing blocks mutually communicate with each other via the interface. By performing the adjustment based on the content, the distribution of compensation for the deterioration factor due to hardware imperfection is optimized, and the characteristic compensation signal processing is performed based on the content of the table. This is a software defined radio device in which each functional block and signal processing block cooperate to realize desired characteristics.

As described above, according to the present invention, each function block of the software defined radio includes the table describing the characteristics (performance) of the function block, and the signal processing unit refers to the table to refer to the entire radio. Is adjusted (negotiation) so as to satisfy the required specifications, and requests for each functional block and the signal processing unit are distributed.

That is, in the present invention, (1) a table (hereinafter referred to as a parameter table) which describes the characteristics and the like for each functional block is provided, and (2) each functional block and the signal processing unit are interconnected. Characterized in that it is a software defined radio having an interface for negotiation.

[0018]

According to the tree invention, by providing a table called a "parameter table" which describes the operation parameters and characteristics of each hardware as a component for each functional block, a plurality of blocks including signal processing blocks are provided. The functional blocks can cooperate to implement the characteristic deterioration compensation.

The parameter table is referred to by a processor arranged on each functional block, and is used for controlling operation parameters when performing control based on a control index from the signal processing unit. Further, in the present invention, each functional block and the signal processing unit are provided with an interface for mutually negotiating.

By negotiation through this interface,
In the system supported by the software defined radio, each function block including the signal processing unit to satisfy the required specifications and the conditions of the signal processing units are assigned, and these cooperate to satisfy the required characteristics. To do it.

In the software defined radio according to the present invention, it is only necessary to satisfy the specifications as a whole system, so that the distribution of the required condition to each functional block and the signal processing unit can be adjusted. Is eliminated, and the capability required for each functional block is reduced, so that a reduction in device scale and low power consumption can be realized.

[0022]

FIG. 1 is a diagram showing an example of an embodiment of the present invention, and corresponds to the first aspect of the present invention. In the figure, numerals 10 to 15 are main signals, 100 is a software defined radio, 200 is an antenna control unit, 210 is an antenna, 250, 350, and 750 are functional block processors, 260 and 360 are parameter tables, and 300 is a radio. 5 shows a signal processing unit.

Further, 400 is a D / A converter, and 500 is A
/ D converter, 600 is a signal processing unit, 700 is an external interface unit, 800 is an external input / output terminal, 850 is software, 900, 910, 920, and 930 are control interfaces, and 940, 950, and 960 are negotiation interfaces. Is represented.

The signal embedding unit 600 includes, via control interfaces 910, 920, and 930, functional blocks including a processor, that is, an antenna control unit 200, a radio signal embedding unit (RF / IF unit) 300, and an external unit. Sends control commands and parameters to the interface unit 700,
Also, information such as an operation state is received from each of these functional blocks.

The antenna control unit 200 and the radio signal processing unit 300 include parameter tables 260 and 360 that describe the characteristics of each built-in hardware unit. Although the external interface 700 requires control such as switching, the electrical characteristics are fixed, and therefore, the present embodiment has no parameter table.

Parameter table 3 in the case where attention is paid to the operation of the high-power amplifier mounted on radio signal processing section 300
Table 1 shows 60 examples. The parameter table 360 also includes characteristics and parameters of hardware other than the high-power amplifier mounted on the wireless signal processing unit 300.

[0027]

[Table 1] Hereinafter, "distribution of compensation for a deterioration factor caused by hardware imperfection is optimized and characteristic compensation signal embedding is performed based on the contents of a parameter table" described in "Claims" An example of the method will be described.

In this example, the efficiency (power consumption), adjacent channel leakage power, various characteristics of the high-output amplifier used (1 dB gain suppression point output power, the amount of improvement by the linearizer, etc.) are determined in accordance with the system requirements of the distortion characteristics. ) Based on the wireless signal processing unit 300 via the negotiation interface 950.
Negotiation is made between the signal processing unit 600 and.

The distribution of the distortion characteristics is determined by this negotiation, the values of the bias and the back-off amount are determined, and the use of the linearizer is selected. If the radio signal processing unit 300 is replaceable, a sufficient amount of back-off can be obtained when an RF / IF unit equipped with a high-power amplifier having sufficient output is used, and a linear system can be easily obtained. The required value can be satisfied.

Here, the back-off amount is 1 dB.
Defined as the difference between the gain suppression point output power and the actual operating output,
It is used as an index for compensating the linearity of the amplifier. On the other hand, when there is no margin in output or when designing with emphasis on efficiency, the amount of back-off cannot be increased, so if necessary, use a linearizer that is baseband signal processing in the signal processing section. Ensure linearity.

As an individual linearizer technology, reference [2]
Proceedings of the 2000 IEICE General Conference, B-5-2
For example, use of a predistortion circuit proposed in “11-214” and the like can be considered. In this method, the input power vs. output power / phase characteristics required for the processing of the linearizer are those described in the parameter table 360.

Further, if the bias voltage can be adjusted, the bias point can be lowered when using a modulation method resistant to distortion (a constant envelope signal such as GMSK or π / 4-QPSK) in the software defined radio apparatus of the present invention. High efficiency can be obtained by performing the class B operation. Conversely, QAM
When using a modulation method that requires equal linearity,
It is necessary to raise the bias point and perform class A operation.

As in the case of the linearizer described above, the bias control is performed based on the characteristics described in the parameter table 360. In the present embodiment, as a specific physical interface used for the control and negotiation interfaces, a dedicated interface may be defined as necessary in consideration of the amount of information and transmission speed. Standards can be used.

That is, in FIG. 1, the interfaces (910, 920, 930, 940, 9
50, 960) are described as individual interfaces, but if possible, they may be realized as a common interface. Further, the control interface and the negotiation interface may be the same interface.

[0035]

The present invention exerts a particularly great effect when each functional block is interchangeable. By referring to the parameter table, even if the function block is replaced,
Hardware characteristics can be effectively compensated without changing the signal processing unit and the software of the processor mounted on each functional block.

By implementing a software defined radio using the present invention, it is not necessary to use a functional block having an unnecessarily high capability (for example, maximum transmission power and linearity in a high-output amplifier). Therefore, not only can the hardware characteristic compensation be effectively realized, but also unnecessary power consumption can be suppressed, and the effect of low power consumption can be obtained.

[Brief description of the drawings]

FIG. 1 is a diagram showing an example of an embodiment of the present invention.

FIG. 2 is a diagram illustrating an example of a configuration of a conventional software defined radio device.

[Explanation of symbols]

10, 11, 12, 13, 14, 15 Main signal 100 Software defined radio 200 Antenna control unit 210 Antenna 250, 350, 750 Function block processor 260, 360 Parameter table 300 Radio signal processing unit 400 D / A converter 500 A / D converter 600 Signal processing unit 700 External interface unit 800 External input / output terminal 850 Software 900, 910, 920, 930 Control interface 940, 950, 960 Negotiation interface

 ────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Akinori Shibuya 2-3-1 Otemachi, Chiyoda-ku, Tokyo F-term in Nippon Telegraph and Telephone Corporation (reference) 5K011 AA04 BA10 DA01 JA01 KA03 5K067 AA41 AA43 EE02 GG01 GG11 HH21 HH23

Claims (2)

[Claims] 1. A signal processing block capable of performing signal processing required for wireless communication and changing its function by replacing software, an antenna unit, a wireless signal processing unit for performing frequency / level conversion, and an external interface unit. Each of the functional blocks includes a signal processing device for setting its function and operation, and the signal processing block and each of the function blocks are connected to each other. A first interface for exchanging information, exchanging information between the signal processing block and any of the functional blocks via the first interface; Recognizing the operation state of the entire wireless device from the information obtained from the functional blocks, the functional blocks include the signal processing block and an optional A software defined radio that performs necessary judgment and setting based on control information obtained from a desired functional block, wherein the functional block is a table in which operating parameters and characteristics of individual hardware constituting itself are described. And a second interface for coordination between the signal processing block and each functional block, wherein each of the functional blocks and the signal processing block mutually communicate with each other via the second interface. Optimizing the distribution of compensation for deterioration factors due to hardware imperfections, and performing characteristic compensation signal processing based on the contents of the table, A software defined radio apparatus wherein a functional block and a signal processing block cooperate to realize desired characteristics. 2. A signal processing block capable of performing signal processing necessary for wireless communication and changing its function by replacing software, an antenna section, a wireless signal processing section for performing frequency / level conversion, and an external interface section. Each of the functional blocks includes a signal processing device for setting its function and operation, and the signal processing block and each of the function blocks are connected to each other. An interface for information exchange is provided, and information is exchanged between the signal processing block and any of the functional blocks via the interface. The signal processing block obtains information obtained from each of the functional blocks. The function block recognizes the operating state of the entire wireless device from the signal processing block and the function processing block and any function block. A software defined radio that makes necessary judgments and settings based on control information obtained from the software, and the function block includes a table describing operation parameters and characteristics of individual hardware constituting the function radio block. The functional blocks and the signal processing blocks mutually adjust based on the contents of the table via the interface to distribute compensation for deterioration factors caused by incomplete hardware. Optimizing, and performing the characteristic compensation signal processing based on the contents of the table, whereby the functional blocks and the signal processing blocks cooperate to realize desired characteristics. apparatus.