FIELD OF THE INVENTION

The invention is related to a receiver comprising a frequency converter for deriving from the input signal of the receiver a plurality of intermediate polyphase signals, the receiver further comprises a polyphase filter for deriving filtered polyphase signals from the intermediate polyphase signals. The invention is also related to a filter arrangement using frequency conversion means and a polyphase filter.

BACKGROUND OF THE INVENTION

Such a receiver and filter arrangement are known from U.S. Pat. No. 4,723,318. In receivers an RF signal is down converted to an IF frequency substantially lower than said RF frequency in order to make it possible to obtain a good adjacent channel selectivity with easy realizable filters. A problem associated with this down conversion is the sensitivity of the receiver for so-called image signals. If the signal to be received has a frequency of f

RF

, the local oscillator to be used in the frequency conversion means has a frequency f

LO

and the IF frequency is equal to f

LO

−f

RF

, the receiver receives also RF signals with a frequency of f

LO

+f

IF

, causing interference to the reception of the desired RF signal with frequency f

RF

.

In order to suppress this undesired effect, often an RF filter is used in front of the frequency conversion means to suppress RF signals with a frequency of f

LO

+f

IF

. This RF filter can be quite expensive.

In the receiver according to the above mentioned US patent, a so called polyphase filter is used for filtering the output signal of the frequency conversion means. Polyphase filters can make use of multiple phase shifted input signals (to be provided by the frequency conversion means) to produce asymmetric transfer functions enabling suppression of signals at the image frequency without requiring an RF filter. The polyphase filter according to the above mentioned US patent is designed for suppressing a signal at an image frequency.

SUMMARY OF THE INVENTION

The object of the present invention is to provide a receiver in which beside the image rejection also the adjacent channel selectivity is realized in a very cost effective way.

Therefor the invention is characterized in that the receiver comprises a further frequency converter for deriving a plurality of further intermediate polyphase signals from the filtered polyphase signals, the receiver comprises a further polyphase filter for deriving further filtered polyphase signals from the further intermediate polyphase signals, one of the polyphase filter and the further polyphase filter being arranged for attenuating signals above a first frequency, and one of the polyphase filter and the further polyphase filter being arranged for attenuating signals below a second frequency.

By using these measures it becomes possible to obtain a receiver with an asymmetric band pass transfer function. The first frequency converter with associated polyphase filter can suppress one part of the input spectrum (e.g. all frequencies below a frequency f

1

) by choosing suitable values for the IF frequency and the first frequency of the (first) polyphase filter, and the second frequency converter with associated polyphase filter can suppress another part of the input spectrum (e.g. all frequencies above a frequency f

2

<f

l

) so that a band pass transfer function is obtained suitable for realizing the adjacent channel selectivity.

It is observed that the article “High performance direct conversion” by R. Green and R. Hoskins in Electronics World, January 1996, pp. 18-22 discloses a receiver in which two polyphase filters are used. However this document does not use a combination of a first polyphase filter suppressing frequencies above (below) a certain frequency, and a second polyphase filter suppressing frequencies below (above) a certain frequency. The absence of said combination results in a spectrum inversion to take place in said receiver, which is in general undesirable in receivers used for receiving digital signals.

An embodiment of the invention is characterized in that the first frequency and the second frequency are substantially zero.

By using polyphase filters with a cut off frequency of substantially zero, it is obtained that this cut off frequency does not depend on the values of the components used in said polyphase filter. The cut off frequency of the combination of frequency converter and polyphase filter is now only determined by the frequency of the local oscillator used in the frequency converter. Because said frequency can be set very accurately, it becomes possible to realize very accurate filters in a cost effective way.

A further embodiment of the invention is characterized in that the first polyphase filter and the second polyphase filter comprise passive filters.

The use of passive filters does not require active elements such like opamps, resulting in lower costs, and often in a more stable operation of the receiver.

A still further embodiment of the invention is characterized in that the first polyphase filter and the second polyphase filter comprise passive filters using capacitors and resistors.

Using passive filters with resistors and capacitors results in a receiver which can easily be realized in standard IC technologies, resulting a very cost effective solution.

A still further embodiment of the invention is characterized in that the further frequency conversion means comprise image rejection mixing means.

By employing an image rejection mixer in the further frequency converter, it becomes possible to choose the intermediate polyphase signal and the further intermediate polyphase signal in the same frequency range without requiring expensive image rejection filters. The possibility to choose the intermediate polyphase signals and the further intermediate polyphase signals in the same frequency range enables the realization of receivers having a narrow IF bandwidth without requiring expensive band-pass filters.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be explained with reference to the drawings. Herein shows:

FIG. 1

, a block diagram of a receiver according to the invention;

FIG. 2

, a plot of the frequency spectra at different positions in the receiver according to

FIG. 1

;

FIG. 3

, a further plot of the frequency spectra at different positions in the receiver according to

FIG. 1

;

FIG. 4

, an implementation of the polyphase filter

16

in the receiver according to

FIG. 1

;

FIG. 5

, an implementation of the mixer

15

in the receiver according to

FIG. 1

;

FIG. 6

, an implementation of the polyphase filter

16

in the receiver according to FIG.

1

.

DETAILED DESCRIPTION OF THE INVENTION

An input of the receiver

2

according to

FIG. 1

is connected to a first input of a mixer

4

. A first output of a local oscillator

6

, carrying an in-phase local oscillator signal, is connected to a second input of the mixer

4

. A second output of the local oscillator

6

, carrying a quadrature local oscillator signal, is connected to a third input of the mixer

4

. The (first) frequency converter

5

is constituted by the combination of the mixer

4

and the local oscillator

6

.

A first output of the mixer

4

, carrying an in-phase component of the intermediate polyphase signal, is connected to a first terminal of a capacitor

8

, and to a first input of an AGC amplifier

12

. A second output of the mixer

4

, carrying a quadrature component of the intermediate polyphase signal, is connected to a first terminal of a capacitor

10

, and to a second input of the AGC amplifier

12

. Second terminals of the capacitors

8

and

10

are connected to ground. It is observed that each of the in-phase component and the quadrature component of the intermediate signals, can be represented by a pair of balanced signals +I, −I and +Q and −Q respectively.

The outputs of the AGC amplifier

12

are connected to inputs of a low-pass filter

14

. The outputs of the low-pass filter

14

are connected to corresponding inputs of the (first) polyphase filter

16

. The outputs of the polyphase filter

16

are connected to inputs of a second AGC amplifier

17

via coupling capacitors

18

and

20

.

The outputs of the second AGC amplifier

17

are connected to the further frequency converter

13

via coupling capacitors

18

and

20

. In the further frequency converter

13

the input signals are applied to corresponding inputs of an image rejection mixer

15

. Outputs of a local oscillator

22

in the further frequency converter, carrying a polyphase local oscillator signal, are connected to corresponding inputs of the image rejection mixer

15

. Outputs of the image rejection mixer

15

, carrying the further intermediate polyphase signals, are connected to inputs of the further polyphase filter

19

. The outputs of the polyphase filter

19

, carrying the further filtered polyphase signals, are connected via coupling capacitors

23

and

25

to corresponding inputs of a demodulator

21

. At the output of the demodulator

21

, a demodulated output signal is available.

The mixer

4

is arranged for mixing the input signal V

RF

of the receiver with an in-phase local oscillator signal, and a quadrature local oscillator signal, both being generated by a local oscillator

6

. The relevant parts of the output signals of the mixer

4

are equal to c·{circumflex over (v)}

RF

·sin(2&pgr;(f

RF

−f

LO1

)·t) and c·{circumflex over (v)}

RF

·cos(2(f

RF

−f

LO1

)·t)respectively, wherein c is a constant, {circumflex over (v)}

RF

is the amplitude of the (sinusoidal) input signal, f

RF

is the frequency of the input signal, and f

LO1

is the frequency of the local oscillator signal. In most implementations, the quadrature signals are present in pairs of balanced signals such that the signals −c·{circumflex over (v)}

RF

·sin(2&pgr;(f

RF

−f

LO1

)·t) and −c·{circumflex over (v)}

RF

·cos(2&pgr;(f

RF

−f

LO1

)·t) are also available.

The capacitors

8

and

10

provide a first filtering of the output signals of the mixer

4

in order to suppress strong out of band signals. The AGC amplifier

12

is present to provide signals having a substantial constant amplitude at the input of the low-pass filter

14

. The low pass filter

14

has a second order Butterworth transfer function with a cut-off frequency around 30 kHz. The low pass filter

14

is present to provide some adjacent channel selectivity.

The polyphase filter

16

is arranged to provide one edge of the final channel selectivity. Preferably the polyphase filter

16

has a cut off frequency of 0 Hz, resulting in a first edge at a frequency of f

RF

−f

LO1

. The output signal of the polyphase filter

18

is amplified by the AGC amplifier

18

to a reference value. The capacitors

18

and

20

are present to eliminate DC offsets from the output signal of the polyphase filter

16

.

The output signal of the AGC amplifier

18

is mixed by the second frequency converter with a local oscillator signal with frequency f

LO2

. The image rejection mixer

15

is arranged to provide only the sum or the difference frequency at its output, dependent on its internal interconnections as will be explained later with reference to FIG.

5

. The output of the image rejection mixer

15

is filtered by the polyphase filter

19

to provide the second edge of the final channel selectivity. Again the cut off frequency of the polyphase filter is preferably equal to 0 Hz, resulting in a second edge at a frequency of f

RF

−f

LO1

−f

LO2

. Consequently a bandpass characteristic is obtained with edges at f

RF

−f

LOI

, and f

RF

−f

LOl

−f

LO2

, respectively. In the case of 0 Hz polyphase filters the accuracy of the position of said edges is not determined by the accuracy of the elements used in the polyphase filters, but only by the accuracy of the frequency of the local oscillator signals.

The output signal of the polyphase filter

19

is presented to a demodulator

21

for demodulation. The capacitors

23

and

25

are present to eliminate offsets from the output signal of the polyphase filter

19

. At the output of the demodulator

21

the demodulated signal is available.

FIG. 2

, shows the spectra at different positions in the receiver in the case the frequency of the first local oscillator is lower than the frequency of the RF signal. Graph

26

shows the relevant parts of the frequency spectrum at the input of the receiver according to FIG.

1

. For clarity it is assumed that only one signal, having a frequency f

RF

, is present. In graph

28

of

FIG. 2

the input signal of the first polyphase filter

16

is presented. The image signal with a frequency of f

RF

+f

LO1

is already suppressed by the low pass filter

14

. Graph

30

of

FIG. 2

shows the transfer function of the first polyphase filter

16

together with the output spectrum of said polyphase filter

16

. The polyphase filter

16

is in this case a polyphase high-pass filter.

Graph

34

of

FIG. 2

shows the spectrum of the output signal of the image rejection mixer

15

. It can be seen that the polyphase mixer

15

is arranged for providing the difference frequency between its input signal and the local oscillator

22

. Finally graph

36

shows the output signal of the polyphase filter

19

in which the filtering by said polyphase filter

19

is shown. Here the polyphase filter

19

is arranged as a low-pass filter passing frequencies below 0 Hz. From graph

36

it can be seen that a band-pass characteristic is obtained by the combination of polyphase filters.

It is observed that it is not necessary that the polyphase filters are high-pass filters or low pass filters. The transfer function for frequencies beyond the edge defined by the other polyphase filter may assume arbitrary values. In practical implementations, the polyphase filters will show a band pass character, of which only one edge is used to define the transfer function of the receiver. This band-pass character is indicated by the dotted line in graphs

30

and

34

. The band pass character mentioned above can also be caused by the Butterworth filter

16

.

FIG. 3

, shows the spectra at different positions in the receiver in the case the frequency of the first local oscillator is higher than the frequency of the RF signal. Graph

38

shows the input spectrum of the receiver. Graph

40

shows the spectrum at the output of the low-pass filter

14

. Graph

42

shows the spectrum of the output signal of the polyphase filter

16

. This graph shows the suppression frequencies above a given frequency. The suppressed frequencies are here the positive frequencies. Graph

44

shows the spectrum of the output signal of the image rejection mixer

15

. From this graph it is clear that only the sum frequencies of the input signal and the local oscillator signal is present in the output signal of the mixer

15

. Consequently the frequency spectrum has been shifted to higher frequencies. Graph

46

shows the spectrum at the output of the second polyphase filter

19

, which filter is arranged for suppressing frequencies below a certain frequency.

In the polyphase filter

6

according to

FIG. 4

, a first (second) [third] {fourth} input, carrying a 0° (90°) [180°]{270°} signal, is connected to an first terminal of a resistor

52

(

70

) [

88

] {

106

} and to a first terminal of a capacitor

99

(

62

) [

80

] {

98

}. A second terminal of the resistor

52

(

70

) [

88

] {

106

} is connected to a second terminal of the capacitor

62

(

80

) [

98

] {

99

}, to a first terminal of a resistor

54

(

72

) [

90

] {

108

} and to a first terminal of a capacitor

64

(

82

) [

100

] {

101

}. A second terminal of the resistor

54

(

72

) [

90

] {

108

} is connected to a second terminal of the capacitor

101

(

64

) [

82

] {

100

}, to a first terminal of a resistor

56

(

74

) [

92

] {

110

}, and to a first terminal of a capacitor

66

(

84

) [

102

] {

103

}. A second terminal of the resistor

56

(

74

) [

92

] {

110

} is connected to a second terminal of the capacitor

103

(

66

) [

84

] {

102

}, and to a first (second) [third] {fourth} input of a buffer circuit

57

.

A first (second) [third] {fourth} output of the buffer circuit

57

, carrying a 0° (90°) [180°]{270°}signal, is connected to an first terminal of a resistor

58

(

76

) [94] {112} and to a first terminal of a capacitor

68

(

86

) [

104

] {

116

}. A second terminal of the resistor

58

(

76

) [

94

] {

112

} is connected to a second terminal of the capacitor

116

(

68

) [

86

] {

104

}, to a first terminal of a resistor

60

(

78

) [

96

] {

114

}, and to a first terminal of a capacitor

69

(

87

) [

97

] {

118

}. A second terminal of the resistor

60

(

78

) [

96

] {

114

} is connected to a second terminal of the capacitor

118

(

69

) [

87

] {

97

}, and to a first (second) [third] {fourth} output of the polyphase filter

6

.

The polyphase filter

6

comprises a cascade connection of three polyphase filter sections, a buffer amplifier and two additional polyphase filter sections. The first section of the polyphase filter

6

, causes a real pole for p=−200 kHz and an imaginary zero for p=+50j kHz. Consequently this first section has a low-pass transfer function. The second section of the polyphase filter

6

has a pole for p=−60 kHz and a zero for p=−46j kHz and the third filter section has a pole for p=−10 kHz, and a zero for −10j kHz. These filter sections have a high-pass transfer function.

The buffer amplifier is present to prevent excessive loading of the first three filter sections by the fourth and fifth filter sections. The fourth filter section has a pole for p=−200 kHz and a zero for −74j kHz and the fifth filter section has a pole for p=−70 kHz and a zero for p=−20 kHz . Consequently both filter sections have a high-pass transfer function. In the image rejection mixer

15

according to

FIG. 5

, balanced in-phase local oscillator signals I

F1

and −I

F1

, are applied to a first pair of inputs of a multiplier

120

and to a first pair of inputs of a multiplier

126

. Balanced quadrature local oscillator signals Q

F1

and −Q

F1

are applied to a first pair of inputs of a multiplier

122

and to a first pair of inputs of a multiplier

124

.

Balanced in-phase input signals I

F2

and −I

F2

are applied to a second pair of inputs of the multiplier

120

and to a second pair of inputs of the multiplier

124

. Balanced quadrature input signals Q

F2

and −Q

F2

are applied to a second pair of inputs of the multiplier

122

and to a second pair of inputs of the multiplier

126

.

Balanced output signals of the multipliers

120

and

122

are connected to a first pair of output terminals carrying quadrature output signals Q

F3

and −Q

F3

. The output signals of the multiplier

120

can be interchanged for purposes explained later. Balanced output signals of the multipliers

124

and

126

are connected to a second pair of output terminals carrying in-phase output signals I

F3

and −I

F3

. The output signals of the multiplier

124

can be interchanged.

For the explanation of the operation of the mixer

15

it is assumed that the signals I

F1

, Q

F1

, I

F2

and Q

F2

are given by:

I

F1

=sin(&ohgr;

1

·t

);

Q

F2

=cos(&ohgr;

1

·t

);

I

F2

=sin(&ohgr;

2

·t

);

Q

F2

=cos(&ohgr;

2

·t

  (1)

Using the expressions according to (1) for the output signals of the mixers

120

,

122

,

124

and

126

can be found:

I

120

=cos{(&ohgr;

1

−&ohgr;

2

)

t

}−cos{(&ohgr;

1

+&ohgr;

2

)

t}

  (2)

I

122

=cos{(&ohgr;

1

−&ohgr;

2

)

t

}−cos{(&ohgr;

1

+&ohgr;

2

)

t}

  (3)

I

124

=cos{(&ohgr;

1

−&ohgr;

2

)

t

}−cos{(&ohgr;

1

+&ohgr;

2

)

t}

  (4)

I

126

=cos{(&ohgr;

1

−&ohgr;

2

)

t

}−cos{(&ohgr;

1

+&ohgr;

2

)

t}

  (5)

If the mixers

122

and

126

are connected according to the dashed lines, the output signal Q

F3

is derived by subtracting the output signal of the mixer

120

from the output signal of the mixer

122

. The output signal I

F3

is obtained by adding the output signal of the mixer

124

to the output signal of the mixer

126

. For I

F3

and Q

F3

is found in this way:

I

F3

=2sin{(&ohgr;

1

+&ohgr;

2

)

t}

  (6)

Q

F3

=2cos{(&ohgr;

1

+&ohgr;

2

)

t}

From (6) it can be seen that only the sum frequency is present in the output signal of the mixer

15

. If the outputs of the mixers

122

and

124

are connected according to the dotted lines, the output signal Q

F3

is obtained by adding the output signal of mixer

120

to the output signal of the mixer

122

. The output signal I

F3

is obtained by subtracting the output signal of the mixer

124

from the output signal of the mixer

126

. For the output signals is found in this way:

I

F3

=2sin{(&ohgr;

1

−&ohgr;

2

)

t}

  (7)

Q

F3

=2cos{(&ohgr;

1

−&ohgr;

2

)

t}

From (7), it can be seen that now only the difference frequency is present in the output signal of the mixer. As explained above, the interconnections of the mixers

120

and

124

can be chosen to select the desired operation of the mixer

15

.

In the polyphase filter

19

according to

FIG. 6

, a first (second) [third] {fourth} input, carrying a 0° (90°) [180°]{270°} signal is applied to a first terminal of a resistor

59

(

67

) [

87

] {

101

} and to a first terminal of a capacitor

61

(

81

) [

95

] {

53

}. A second terminal of the resistor

59

(

67

) [

87

] {

101

} is connected to a second terminal of the capacitor

53

(

61

) [

81

] {

95

}, to a first terminal of a resistor

51

(

71

) [

91

] {

103

}, and to a first terminal of a capacitor

55

(

63

) [

83

] {

97

}.

A second terminal of the resistor

51

(

71

) [

91

] {

103

}, is connected to an first terminal of a resistor

49

(

73

) [

93

] {

105

} and to a first terminal of a capacitor

57

(

65

) [

85

] {

99

}. A second terminal of the resistor

49

(

73

) [

93

] {

105

} is connected to a second terminal of the capacitor

65

(

85

) [

99

] {

57

} and to a first (second) [third] {fourth} output terminal. The polyphase filter

19

comprises a cascade connection of three passive first order sections. The first section has a pole for p=−200 kHz and a zero for p=−74j. This section has a high-pass transfer function. The second section has a pole for p=−120 and a zero for p=+40j, and the third section has a pole for p=−75 and a zero for p=−25j. The second and third filter sections show a low-pass transfer function. With the implementation of the polyphase filters

14

and

19

as explained above, the polyphase mixer

15

has to be set to obtain the difference frequency, leading to frequency spectra in the receiver according to FIG.

2

.