KR20120070806A - Apparatus for up-converting digital radio frequency - Google Patents

Abstract

The present invention relates to a digital radio frequency upconversion device. More specifically, the present invention relates to a digital radio frequency upconversion device for upgrading a digital signal to a frequency of a wideband RF signal in order to modulate and transmit the baseband digital signal into a radio frequency (RF) signal. In accordance with another aspect of the present invention, a digital radio frequency upconversion device having a digital modulator includes: a receiver converting a digital signal into an I signal and a Q signal; A pulse shaping filter receiving I and Q signals from the receiver and limiting frequency bands of the I and Q signals; A first interpolation unit which performs interpolation to increase the sample rates of the I and Q signals; A quadrature modulator configured to receive the I and Q signals from the first interpolation unit, a numerically controlled oscillator for oscillating a cosine signal and a sine signal, and a multiplier and an adder for modulating the I and Q signals; And a DAC for converting the digital signal modulated by the quadrature modulator into a wideband RF signal.

Description

Digital radio frequency up-conversion device {APPARATUS FOR UP-CONVERTING DIGITAL RADIO FREQUENCY}

The present invention relates to a digital radio frequency upconversion device. More specifically, the present invention relates to a digital radio frequency upconversion device for upgrading a digital signal to a frequency of a wideband RF signal in order to modulate and transmit the baseband digital signal into a radio frequency (RF) signal.

In a broadband wireless transmission system, a modulator for modulating a transmission signal to an intermediate frequency (IF) of a radio frequency and an up converter for receiving an intermediate frequency and then upgrading it to a desired radio frequency (RF). The intermediate frequency is used in various ways such as 36MHz, 44MHz, 70MHz depending on the characteristics of the wireless system. Generally, 36MHz and 44MHz are used for video transmission, and various intermediate frequencies such as 70MHz and 140MHz are used for other wireless communication systems.

The transmission of terrestrial TV and cable TV, military communication, and satellite communication use a very wide frequency band. Especially, terrestrial TV and cable TV use 50-860MHz, and the bandwidth reaches tens of octaves. A device that takes an intermediate frequency and converts the frequency into an arbitrary frequency within a frequency range of tens of octaves is called a wideband upconversion device.

Conventional wideband upconversion device performs an analog conversion, the frequency conversion of the RF signal using a mixer and a voltage controlled oscillator. However, analogue frequency converters are vulnerable to ambient noise and are difficult to integrate due to the different size of components depending on the frequency. In addition, the characteristics of the device may change due to the error of the device value, the temperature change, and the change of the device value according to the secular variation, which may affect the performance of the equipment. These analog devices have a problem in that a lot of adjustment is required in production, making mass production difficult, expensive, and periodically requiring inspection and maintenance.

The present invention has been made to solve the above problems, by configuring the analog radio frequency up-conversion device as a digital element, digital radio frequency up-conversion to solve the degradation of the analog device, the impossibility of integration and user inconvenience It is an object to provide a device.

Digital radio frequency up-conversion device combined with a digital modulator according to an embodiment of the present invention,

A receiver for converting a digital signal into an I signal and a Q signal; A pulse shaping filter receiving I and Q signals from the receiver and limiting frequency bands of the I and Q signals; A first interpolation unit which performs interpolation to increase the sample rates of the I and Q signals; A quadrature modulator configured to receive the I and Q signals from the first interpolation unit, a numerically controlled oscillator for oscillating a cosine signal and a sine signal, and a multiplier and an adder for modulating the I and Q signals; And a DAC for converting the digital signal modulated by the quadrature modulator into a wideband RF signal.

The apparatus for digital uplink frequency conversion may further include a second interpolation unit which performs interpolation to increase the sample rate of the digital signal modulated by the quadrature modulator.

Digital radio frequency up-conversion device according to another embodiment of the present invention,

An ADC for converting an analog IF signal into a digital signal; A quadrature demodulator receiving the digital signal from the ADC, demodulating the signal into an I signal and a Q signal, and reducing their frequencies to convert to a baseband digital signal; An LPF receiving I and Q signals from the quadrature demodulator and removing their harmonics; A first interpolation unit which performs interpolation to increase the sample rates of the I and Q signals; A quadrature modulator configured to receive the I and Q signals from the first interpolation unit, a numerically controlled oscillator for oscillating a cosine signal and a sine signal, and a multiplier and an adder for modulating the I and Q signals; And a DAC for converting the digital signal modulated by the quadrature modulator into a wideband RF signal.

The apparatus for digital uplink frequency conversion may further include a second interpolation unit which performs interpolation to increase the sample rate of the digital signal modulated by the quadrature modulator.

By means of the above solution, the digital element with high reliability of the radio frequency upconversion device prevents the change of the element value due to temperature change or secular variation, enables mass production of the frequency upconverter, Modulators can be implemented at low cost.

In addition, it is also possible to develop a wireless communication and broadcasting device using a wide frequency. As a result, various signals, including digital TV signals, can be transmitted more quietly than in the case of using analog devices.

1 is a block diagram showing the configuration of a conventional analog radio frequency upconversion device.
2 is a block diagram showing the configuration of a digital radio frequency up-conversion device combined with a digital modulator according to an embodiment of the present invention.
3 is a block diagram illustrating a configuration of a digital radio frequency upconversion device according to another embodiment of the present invention.

Hereinafter, the present invention will be described in detail through exemplary embodiments with reference to the accompanying drawings, and the present invention is not limited thereto. In addition, detailed descriptions of well-known functions and configurations that may blur the gist of the present invention will be omitted.

1 is a block diagram showing the configuration of a conventional analog radio frequency upconversion device.

Conventional analog radio frequency up-conversion device is a super heterodyne system, and includes a device such as an analog mixer 120, a fixed voltage controlled oscillator 140, a wideband voltage controlled oscillator 150, and an analog filter 160. It is composed.

When a digital signal is received, it is converted into an analog IF signal, and the analog IF signal is mixed with the signal oscillated through the fixed voltage controlled oscillator 140 and converted into a second IF signal, which is converted into a wideband voltage control. It is mixed with the oscillator 150, converted back to any wideband RF signal and sent out.

However, such an analog radio frequency upconversion device, as discussed above, is vulnerable to ambient noise and difficult to integrate. In addition, there is a problem that can affect the performance of the equipment by changing the characteristics due to the change in the value of the device according to the error, temperature change and secular variation of the device value.

2 is a block diagram showing the configuration of a digital radio frequency up-converter 200 combined with a digital modulator according to an embodiment of the present invention.

The receiver 210 receives the baseband digital signal and converts the baseband digital signal into an in-phase signal (hereinafter referred to as I signal) and a quadrature (hereinafter referred to as Q signal) signal.

Digital signals are converted into I and Q signals and quadrature modulated. This modulation method is called in-phase / quadrature (I / Q) modulation. I / Q modulation is a method of transmitting two separate channels of information, where the carrier signal is shifted to produce two carriers in a sin and cosine version. Two modulation inputs are applied to two separate modulators, each of which is fed a signed or cosine carrier. The outputs of the two modulators are logarithmically summed and the result is one signal to be transmitted containing I and Q information. Upon receipt, the composite signals I and Q are processed and extracted by a receiver using carrier replicas (sign and cosine).

Modulation of the digital signal to the I signal and the Q signal can be used in a variety of ways within a range apparent to those skilled in the art.

The digital pulse shaping filter 220 is essentially used in a digital communication system, and converts a symbol of an input signal into a shape of a specific waveform, thereby limiting a frequency band.

The digital signal passing through the pulse shaping filter 220 passes through the first interpolation unit 230 that performs interpolation to increase the sample rate of the digital signal.

Since the digital signal must be modulated with a high frequency RF signal, quadrature modulator 240 is composed of a numerically controlled oscillator (NCO), two multipliers and an adder, and a cosine signal in the numerically controlled oscillator. And oscillate a sin signal, and perform modulation of the I signal and the Q signal.

The numerically controlled oscillator 240 corresponds to the voltage controlled oscillator 140 in the analog domain and is an oscillator used in the digital domain. Referring to the operation of the voltage controlled oscillator 140, the input of the voltage controlled oscillator 140 is a voltage, the output is the frequency of the oscillator. The entire unit of the voltage controlled oscillator 140 is output / input to be rad / v. As the input voltage increases, the output frequency increases, and this characteristic is used for PLL. In the digital domain, a device having the same characteristics as the voltage controlled oscillator 140 in the analog domain is referred to as a numerically controlled oscillator in that it uses a multi-bit number as an input instead of a voltage.

The digital signal may be interpolated by the second interpolation unit 250 to increase the sample rate.

Finally, the digital signal is converted into a high frequency RF signal and transmitted through the DAC 260 (Digital-Analog Conveter). In order to process wideband RF signals of 50 to 860 MHz used in the digital TV field in the digital domain, the DAC 260 may be a high speed DAC 260 having a conversion frequency of 2 GHz.

3 is a block diagram illustrating a configuration of a digital radio frequency up-conversion device 300 according to another embodiment of the present invention.

When the analog IF signal is received, the received IF signal is amplified and filtered, and converted into a digital signal through an analog-digital conveter (ADC) 310.

The digital signal is separated into an I signal and a Q signal through the quadrature demodulator 320, and the IF signal is converted into a baseband signal. The converted baseband digital signal is subjected to a low pass filter (LPF) 330 to remove harmonic components.

Thereafter, as described with reference to FIG. 2, the digital signal is converted into a wideband RF signal through the first interpolation unit 340, the quadrature modulator 350, the second interpolation unit 360, and the DAC 370 to be transmitted. do.

The digital radio frequency up-conversion apparatus (200, 300) of the present invention can be used in the digital TV transmitter and the like described above, it is possible to develop a multi-channel modulator (modulator) and a remodulator through the high integration of the digital unit In particular, it may be utilized in base station equipment or repeaters for mobile communication.

As mentioned above, although this invention was demonstrated to the said Example, this invention is not limited to this. It will be understood by those skilled in the art that modifications and variations may be made without departing from the spirit and scope of the invention, and that such modifications and variations are also contemplated by the present invention.

120: analog mixer
140: fixed voltage controlled oscillator
150: wideband voltage controlled oscillator
160: analog filter
200, 300: digital radio frequency converter
210: receiver
220: pulse shaping filter
230, 340: first interpolation unit
240, 350: quadrature modulator
250, 360: second interpolation unit
260, 370: DAC
310: ADC
320: quadrature demodulator
330: LPF

Claims (4)

A receiver for converting a digital signal into an I signal and a Q signal;
A pulse shaping filter receiving I and Q signals from the receiver and limiting frequency bands of the I and Q signals;
A first interpolation unit which performs interpolation to increase the sample rates of the I and Q signals;
A quadrature modulator configured to receive the I and Q signals from the first interpolation unit, a numerically controlled oscillator for oscillating a cosine signal and a sine signal, and a multiplier and an adder for modulating the I and Q signals; And
And a DAC for converting the digital signal modulated by the quadrature modulator into a wideband RF signal.
The apparatus of claim 1, wherein the digital radio frequency upconversion device is
And a second interpolation unit which performs interpolation to increase a sample rate of the digital signal modulated by the quadrature modulator.
An ADC for converting an analog IF signal into a digital signal;
A quadrature demodulator receiving the digital signal from the ADC, demodulating the signal into an I signal and a Q signal, and reducing their frequencies to convert to a baseband digital signal;
An LPF receiving I and Q signals from the quadrature demodulator and removing their harmonics;
A first interpolation unit which performs interpolation to increase the sample rates of the I and Q signals;
A quadrature modulator configured to receive the I and Q signals from the first interpolation unit, a numerically controlled oscillator for oscillating a cosine signal and a sine signal, and a multiplier and an adder for modulating the I and Q signals; And
And a DAC for converting the digital signal modulated by the quadrature modulator into a wideband RF signal.
The method of claim 3,
The digital radio frequency up-conversion device,
And a second interpolation unit which performs interpolation to increase a sample rate of the digital signal modulated by the quadrature modulator.

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