KR20030064374A - Block communication transceivers with gps capability - Google Patents

Abstract

According to the present invention, a communication system is disclosed that can communicate an RF signal to any one of a plurality of communication standards via a common antenna. The communication system comprises a transmitting unit having at least one transmitting RF information signal output and a receiving unit having at least one receiving RF information signal input and an RF information signal input of GPS. The transmitting unit includes a modulator for modulating the transmission IF into a transmission baseband information signal to generate a transmission IF information signal, and an upconverter for upconverting the transmission IF information signal to transmission RF to generate at least one transmission RF information signal. Equipped. The receiving unit includes a receiving downconverter for white converting at least one receiving RF information signal to a receiving RF to generate a receiving IF information signal, and downconverting the RF information signal of the GPS to a receiving RF to generate the IF information signal of the GPS. And a demodulator for demodulating the received IF to generate a GPS and receive baseband signal. The antenna is coupled to at least one transmit RF information signal output, at least one receive RF information signal input and an RF information signal input of GPS for transmitting and receiving the RF information signal.

Description

BLOCK COMMUNICATION TRANSCEIVERS WITH GPS CAPABILITY

Minimizing the size, weight, and complexity of various electronic devices, particularly personal communication devices such as cellular phones, personal pagers and cordless phones, is becoming increasingly important. One way to minimize these characteristics is to minimize the number and function of components required for an electronic device, or to perform multiple functions in one component. However, personal communication devices, such as cell phones, often require complex circuitry employing components that require a large number of power inefficient components to perform certain functions. This is even more prominent in the field of modern cellular communications, as several different communications standards are employed worldwide and consumers and manufacturers strongly desire to be flexible to operate cell phones under these multiple standards.

For example, the Global System for Mobile 900 (GSM900) is a digital cellular standard operating in the 900 Mhz frequency band currently used in Europe and Asia. The DCS1800 is based on GSM technology and is another digital cellular standard that operates in the 1800 Mhz frequency band, also used in Europe and Asia. The United States uses the PCS1900, a third-generation digital cellular standard similar to the DCS1800, which operates in the 1900 Mhz band. Multi-band cellular phones that can operate in all these standards offer a wide range of applicability to consumers, and offer manufacturers the cost benefits of common designs.

However, multiband cellular phones have some design difficulties. Conventional single band transmitters required two separate frequencies, a fixed intermediate frequency (IF) for modulation and a tunable RF for upconversion. Also, conventional single band transmitters typically require two separate frequencies, tunable RF for down conversion and fixed IF for demodulation. Thus, single band cell phones may require four different frequency sources. Multiband cellular phones increase this problem because different frequencies may be required for modulation, upconversion, downconversion, and demodulation processing in each frequency band. Moreover, different frequencies employed for each band may require different filters for the transmit and receive functions in each band.

The portability of the cell phone leads to additional design problems that are independent of the existing functionality of the cell phone. In a U.S.-wide 911 system for emergency response, a 911 operator is typically provided with the location of the telephone from which the 911 request was initiated to assist emergency responders responding to the distress request. However, because cell phones are mobile, current methods for tracking 911 call alerts cannot provide a location when calling a cell phone. The problem is not trivial, according to research showing that 30-40% of 911 calls are made from cell phones. To solve this problem, the Federal Communications Commission (FCC) mandated that by the end of 2001, cellular service providers should be able to automatically locate locations within 20 meters when calling 911 in addition to basic cellular communications. This location capability is referred to in the industry and herein as "E911 support."

Even if it is not an emergency, knowing where a cell phone is is of great concern to consumers. Travelers in unfamiliar areas can use their cell phones to identify their current location and to instruct them on how to proceed to their desired destination. Conversely, people in unfamiliar areas can use their cell phones to identify their current location and to help others know where they are. Cellular phones capable of providing location information can also be useful for business travelers who rent a car with a navigation system that can utilize such location information. Real estate brokers and delivery service providers may also use location information to help locate a home or business.

Thus, both the requirements imposed by the FCC on the location information of cellular phones and the consumer's demands have formed a market for cellular phones with complex service capabilities, and have led to cellular phones of minimum size, weight, complexity, power consumption and price. The reason for the design challenge to manufacture was increased.

FIELD OF THE INVENTION The present invention relates generally to processing using communication systems and radio frequency (RF) transmitters and receivers (hereinafter referred to as transceivers), specifically the size, weight, complexity, power consumption and cost of function blocks. The present invention relates to a composite service system and processing having a communication and satellite positioning system (GPS) processing function that minimizes the number of points.

1 is a block diagram illustrating a system environment in accordance with an exemplary embodiment of the present invention.

2 is a block diagram illustrating in more detail the modulator of the system shown in FIG. 1;

3 is a block diagram illustrating a composite function block.

4 is a block diagram illustrating a complete GPS processor coupled to a demodulator providing full GPS resolution in accordance with an embodiment of the present invention.

5 is a block diagram illustrating a demodulator comprised of a Coleman filter providing E911 support in accordance with an embodiment of the present invention.

Detailed description of the preferred embodiment

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments will now be described with reference to the accompanying drawings, which are a part of this specification and show specific embodiments in which the invention will be practiced. It will be appreciated that other embodiments may be utilized or structural changes may be made without departing from the scope of the preferred embodiments of the present invention.

Cellular communication systems employ several different communication standards around the world. With the flexibility to operate under multiple communication standards, multiband cellular phones offer consumers greater flexibility and cost manufacturers through common designs. It offers the benefit of savings.

In order to realize a cost-effective design, multiband cellular phones must be minimized in size, weight, complexity, and power consumption. However, the mobility of a cell phone introduces additional requirements that are not related to the basic functionality of the cell phone, which creates a design burden. Because cellular phones are mobile, the FCC required cellular service providers to provide E911 support by the end of 2001, which is the ability to automatically locate the cell phone that made the 911 emergency call. Even in non-emergency situations, information about the cell phone location helps assist the operator while driving. These capabilities, imposed by the FCC and required by consumers, add to the design challenges of minimizing the size, weight, complexity, power consumption, and cost of cell phones.

In an embodiment of the invention, GPS technology is used to generate location information. GPS is a system that utilizes a GPS satellite group to identify a receiver position of a GPS signal transmitted by the GPS satellite group. GPS's full capabilities are not required for E911 support. A cellular phone with only E911 support according to an embodiment of the present invention utilizes only a fraction of the processing power of the overall GPS solution and transmits the information to a server in the base station where the calculation is performed. However, embodiments of the present invention also have a cellular phone with a GPS solution before it includes a basic GPS engine, and perform most or all of the RF and baseband processing and acquisition in the cellular phone. For full GPS capability, GPS may be called at a given time to provide the longitude and latitude coordinates (or other topographical coordinate information) of the cellular phone.

Accordingly, embodiments of the present invention relate to the sharing of functional block communication transceivers with GPS capability to share frequency sources, amplifiers, and mixers between band and service. However, it should be noted that the transceiver according to the embodiment of the present invention is not unique to cellular communication, and may be used in various communication electronic fields including a wireless transmission system and a wired system. Accordingly, embodiments of the invention described herein may include various types of communication systems. However, in order to simplify the disclosure of the present invention, in the present specification, preferred embodiments of the present invention include, but are not limited to, a digital mobile telephone, a digital cordless telephone, a digital pager, a combination thereof, and the like. This is explained in connection with. Such personal communication systems typically include one or more portable, ie remotely located receiver units and / or transmitter units.

In particular, for purposes of illustration, the following description will focus on GPS and one cellular communication standard, code division multiple access scheme (CDMA). In the case of CDMA-900, the frequency band is allocated such that the mobile subscriber unit transmits signals in the transmission band of 824-849 MHz and receives signals in the reception band of 869-894 MHz. In addition, the capabilities of the CDMA-900 described herein can operate in the Analog Advanced Mobile Phone System (AMPS) mode when CDMA services are unavailable. However, the following CDMA example may also apply to CDMA-1900 (CDMA operating in the 1900 MHz band) or any other communication standard. It should also be noted that other communication standards (eg, but not limited to GSM, EGSM, DCS and PCS) may also be used in combination with GPS capabilities in a manner similar to that described herein for CDMA. .

1 shows a generalized representation of a communication system according to an embodiment of the invention. In FIG. 1, the transceiver 10 comprises a transmitting unit 12 and a receiving unit 14, which are coupled for communication via a communication channel 42. Transmission unit 12 includes a modulator 16, which is coupled to receive a transmission baseband information signal 18 from a signal source (not shown in FIG. 1). In one exemplary embodiment, the signal source comprises, for example, a microphone for converting a sound wave into an electronic signal, and a sampling and analog-digital for sampling the electronic signal to convert it into a digital signal representing the acoustic wave. Converter electronic device. In other embodiments, the signal source may be any suitable device (eg, keyboard, digital voice encoder, mouse or other user input device, sensor, monitor or testing device, etc.) for generating a digital data signal for communication over communication channel 42. The same, but not limited to these).

The modulator 16 provides the transmit IF information signal 32 as an output to the transmitter 20. The transmit RF information signal 26 is generated by the transmitter 20 and transmitted from the antenna 22. The receiving unit 14 includes a receiver 24 coupled to the antenna 22 for processing the received RF information signal 44. Receiver 24 provides modulated receive IF information signal 34 to demodulator 28, which demodulates receive IF information signal 34 and generates receive baseband information signal 46. .

The received baseband information signal 46 demodulated from the demodulator 28 is provided to an electronic device for signal processing, an electronic device for sound generation, and the like according to the use characteristics of the transceiver 10. The transmitting unit 12 and the receiving unit 14 are provided with additional components, power supplies, etc., which are known in the art to effect signal transmission and reception and to perform other functions specific to the nature and application of the transceiver 10 usage. It is included.

In the case of a preferred transceiver embodiment, such as a cellular telephone embodiment or a cordless telephone embodiment, each transmitting unit 12 and receiving unit 14 are configured to function as both a transmitting unit and a receiving unit. In the case of one system embodiment, the transmitting unit 12 and the receiving unit 14 send and receive signals directly between them. In other system embodiments, the transmitting unit 12 and the receiving unit 14 communicate via one or more additional transceiver stations 30 (eg, repeaters, base stations or cell stations, etc.).

As shown in the modulator 16 of FIG. 2, in the digital cellular telephone system embodiment and the cordless telephone system embodiment, the transmission baseband information signal 18 is sampled in the form of a baseband I channel signal and a Q channel signal. A voice (or acoustic) signal is provided to the encoder 36. In one preferred cellular telephony embodiment, encoder 36 consists of a phase shift encoder such as, but not limited to, a π / 4 shift quadrature phase shift mapper (π / 4 DQPSK) with a differential encoder, The shaping filter 38 consists of a pulse shaping filter for smoothing the output signal of the encoder. Examples of π / 4 DQPSK and pulse-molded electronics are the papers published by Sakaki Detsu, Seki Ganzuhiko, Kubota Shuji and Kato Shuzo at the 5th IEEE International Symposium on Personal, Indoor and Mobile Radio Communications in 1994. / 4-shift QPSK Digital Modulator LSIC for Personal Communication Terminals "(incorporated herein by reference). Other embodiments may use other suitable encoding schemes, including but not limited to amplitude shift schemes and frequency shift schemes.

The I and Q outputs of the encoder pass through the shaping filter 38 and then proceed to the frequency conversion and modulation electronics 40, which output is comprised of a transmission IF information signal 32. Subsequently, the transmission IF information signal 32 is provided to the transmitter 20 shown in FIG. 1, which transmits the transmission RF information signal 26 to the antenna 22.

3 illustrates a shared functional block communication transceiver having GPS capability 48 in accordance with an embodiment of the present invention. The transceiver 48 includes the modulator 16 described above with reference to FIG. For purposes of illustration and description, the communication transceiver having the GPS capability 48 of FIG. 3 is switchable between the CDMA communication standard and the GPS communication standard.

In the CDMA transmission path, the frequency conversion and modulation electronics 40 receives the I output and Q output of the shaping filter 38 and modulates the transmission IF LO 50 having this I output and Q output to transmit the transmission IF information. Generate signal 32. Transmit IF LO 50 is generated by transmit IF frequency generator 52 having a transmit IF frequency source 54 phase locked to reference source 58 by transmit IF loop electronics 56. In a preferred embodiment of the present invention, the transmit IF frequency source 54 is a voltage controlled oscillator (VCO). However, in another embodiment of the present invention, transmit IF frequency source 54 is any suitable frequency source.

The transmit IF information signal 32 is then amplified by a transmit IF variable gain amplifier (VGA) 60 in the transmitter 20. The CDMA communication standard requires transmit power control of +23 kHz to -50 kHz at the antenna, representing a dynamic range requirement of 73 kHz. Transmit IF VGA 60 performs this power control by adjusting its gain based on commands received from the base station.

The output of transmit IF VGA 60 is then filtered by transmit IF filter 62, which filters the noise generated by transmit IF VGA 60 in the receive band and receives the receive band. Meets noise floor requirements. The transmit IF filter 62 is sufficient to pass a modulated and amplified transmit IF information signal whose center frequency approximately matches the IF carrier frequency and whose bandwidth has minimal distortion. In the CDMA example of FIG. 3, the modulation bandwidth of the transmission IF information signal is 1.25 MHz, and therefore the bandwidth of the transmission IF filter 62 should be at least 1.25 MHz. In a preferred embodiment, the bandwidth of the transmit IF filter 62 is about 5 MHz. The modulated, amplified and filtered transmit IF information signal is then mixed with transmit RF LO 64 in transmit upconverter mixer 66. In a preferred embodiment, transmit upconverter mixer 66 generates a difference between the output of transmit IF filter 62 and transmit RF LO 64. In another (non-CDMA) embodiment, the transmit upconverter mixer 66 is replaced with a switched loop upconverter (not shown in FIG. 3).

In an embodiment of the invention, the transmit RF LO 64 includes a transmit RF frequency generator 68 that includes a transmit RF frequency source 70 phase locked to the reference source 58 by a transmit RF loop electronic 72. Is generated by In a preferred embodiment, the transmit RF frequency source 70 has a VCO. However, in other embodiments, the transmit RF frequency source 70 may be any suitable frequency source.

The output of the transmit upconverter mixer 66 is filtered by the first transmit RF filter 74, which is the spurious frequency generated by the transmit upconverter mixer 66. It has a passband covering the CDMA / Analog AMPS transmission band of 824-849 MHz to eliminate TP. The output of the first transmit RF filter 74 is then amplified by the transmit RF driver amplifier 76, which receives the low level output of the first transmit RF filter 74 and sends it 0.10 dBm. Amplify up to the middle level of multiples of. The output of transmit RF driver amplifier 76 is then filtered by a second transmit RF filter 78, which second CDMA / analog AMPS generated by transmit RF driver amplifier 76. In order to filter out the noise of the reception band, it has a passband covering the CDMA / analog AMPS transmission band of 824-849 MHz. The output of the second transmit RF filter 78 is then amplified by the transmit RF power amplifier 80 to generate the transmit RF information signal 26 at a level sufficient to meet the output power requirements of the antenna 22. . The transmit RF information signal 26 is then filtered by the duplexer 82, which is used to filter out of band noise generated by the transmit RF power amplifier 80. It has a transmission passband covering a CDMA / analog AMPS transmission band of 849 MHz. The output of the duplexer 82 then passes through a service select switch 84 in the antenna coupling electronics 86 before being transmitted by the antenna 22.

In the CDMA / analog AMPS receive path, the signal from the antenna 22 is input to the antenna coupling electronics 86, and in the antenna coupling electronic 86, the signal from the antenna 22 is connected to the service selection switch ( 84) and is filtered by duplexer 82 (which has a receive passband covering the CDMA / analog AMPS receive band of 869-894 MHz to pass only CDMA / analog AMPS signals). The output of the duplexer 82 is a receive RF information signal 44, which passes through the variable gain attenuator 88 of the preferred embodiment of the present invention. Variable gain attenuator 88 selectively attenuates the received signal to meet the CDMA communication standard cellular receive band modulation requirements. However, in other embodiments, attenuation control is achieved by selectively bypassing the receive RF low noise amplifier (LNA) 90, or the variable gain receive RF LNA 90 may be employed instead of the variable gain attenuator 88.

Thereafter, the output of the variable gain attenuator 88 is amplified by the receiving RF LNA 90. In a preferred embodiment of the invention, the received RF LNA 90 has a gain of approximately 20 dB and a noise figure (NF) of approximately 1.5 dB.

Thereafter, the output of the receive RF LNA 90 is filtered by the receive RF picture blocking filter 92. The receive RF picture block filter 92 is a band pass filter having a bandwidth including a CDMA / analog AMPS receive band of 869 to 894 MHz to filter the picture noise generated by the receive RF LNA 90, and the receive RF LNA ( 90 may mix with receive RF LO 94 in receive downconverter mixer 96 and generate unwanted signals in the IF band. In another embodiment, an image reject mixer can be used to eliminate the need for an RF image cut filter.

In an embodiment of the invention, the receive RF LO 94 is connected to a receive RF frequency generator 130 consisting of a receive RF frequency source 134 phase locked to a reference source 58 by a receive RF loop electronic 136. Is caused by. In a preferred embodiment, the receive RF frequency source 134 is a VCO. However, in another embodiment, receive RF frequency source 134 may be any adjustable frequency source.

In a preferred embodiment of the present invention, the receive downconverter mixer 96 generates a difference between the output of the receive RF picture block filter 92 and the receive RF LO 94 designated herein as the receive IF information signal 158. do. The receive IF information signal 158 is then either narrowband CDMA receive IF filter 98 having a bandwidth comprising a CDMA modulation bandwidth of 1.25 MHz or narrowband AMPS receive IF having a bandwidth comprising an AMPS modulation bandwidth of 30 Hz. Pass through filter 99. The selection of the filter may be selected to be switchable depending on whether CDMA or AMPS is used. These filters remove the pseudo frequency generated by the receive downconverter mixer 96. The outputs of narrowband CDMA receive IF filter 8 \ 98 and narrowband AMPS receive IF filter 99 are then supplied to common IF VGA 100. In a preferred embodiment, common IF VGA 100 has a dynamic range of approximately 90 dB. The common IF VGA 100 provides automatic gain control by adjusting the gain to maintain a relatively constant level with the quantizer 118 in the receive path. The output of the common IF VGA 100 is a common IF information signal 156.

The common IF information signal 156 is mixed with the receiving IF LO 132 and demodulated by the frequency conversion and demodulation electronics 114 in the demodulator 28. In an embodiment of the invention, the receive IF LO 132 is generated by a receive IF frequency generator 122, which is received by the receive IF loop electronics 128 by the reference source 58. Consists of a receiving IF frequency source 124 which is phase locked to the " In a preferred embodiment, the receiving IF frequency source 124 is a VCO. However, in another embodiment, receive IF frequency source 124 may be any adjustable frequency source.

The frequency conversion and demodulation electronics 114 generate a baseband information signal 148, which is defined herein as a DC or " near DC " IF (eg, a center frequency of approximately 1 MHz). In the CDMA mode, this baseband information signal 148 is sent to the CDMA baseband filter 116 and the analogue AMPS baseband filter 140 to remove pseudo frequencies generated by the frequency conversion and demodulation electronics 114. It contains the received baseband signal that is filtered by. The analogue AMPS baseband filter 140 has a bandwidth of approximately 30 Hz to accommodate the modulation bandwidth of the analog AMPS receive baseband signal, and is a low pass filter when the receiving baseband signal is DC, and the receiving baseband signal is In the case of DC, it may be a band pass filter. The CDMA baseband filter 116 has a bandwidth of approximately 1.25 MHz to accommodate the modulation bandwidth of the CDMA receive baseband signal, is a low pass filter when the receive baseband signal is DC, and the receive baseband signal is near DC. In this case, it may be a band pass filter. The filtered and demodulated receive baseband signal is then processed by quantizer 118, which generates CDMA I and Q outputs 150 and analog AMPS I and Q outputs 152. . In a preferred embodiment, quantizer 118 is an analog to digital converter (ADC).

In the GPS receive path, the GPS RF information signal 104 collected from the antenna 22 only has a preselector having a band that includes a GPS receive band of 1575.42 MHz ± 1 MHz to pass only the GPS frequency and remove the out of band frequency. Pass through filter 102 and service select switch 84. The filtered GPS RF information signal is then passed through the GPS RF LNA 106 to amplify the GPS RF information signal received from the antenna 22. In a preferred embodiment of the present invention, the GPS RF LNA 106 has a gain of approximately 20 dB and a noise figure (NF) of approximately 1.5 dB.

Thereafter, the output of the received GPS RF LNA 106 is filtered by the GPS RF image blocking filter 108. The GPS RF image blocking filter 108 is a baseband filter having a bandwidth of approximately 1575.42 MHz ± 1 MHz to filter the image noise generated by the GPS RF LNA 106, which is the receiving RF It can mix with the LO 94 and generate unwanted signals in the IF band. In another embodiment, an image reject mixer can be used to eliminate the need for an RF image cut filter.

In an embodiment of the present invention, the GPS downconverter mixer 110 generates a difference between the output of the GPS RF image blocking filter 108 and the receiving RF LO 94, which is designated herein as the GPS IF information signal 160. do. Since the RF frequencies of CDMA and GPS are different, the receive RF LO 94 used by the GPS downconverter mixer 110 is not generated by the receive RF frequency source 134. Instead, the receive RF LO 94 used by the GPS downconverter mixer 110 is generated by the GPS RF frequency source 138 in parallel with the receive RF frequency source 134 and the receive RF loop electronics 136. Is phase locked to the reference source 58. In a preferred embodiment, the GPS RF frequency source 138 is a VCO. However, in another embodiment, the GPS RF frequency source 138 may be any adjustable frequency source.

The GPS IF information signal 160 then passes through a narrowband GPS IF filter 112 to filter out pseudo frequencies generated by the GPS downconverter mixer 110. Narrowband GPS IF filter 112 has a bandwidth of approximately 2 MHz to accommodate the GPS modulation bandwidth. The output of narrowband GPS IF filter 112 is then amplified by common IF VGA 100. In another embodiment, the receiver front end functional block when the narrowband GPS IF filter 112 and the narrowband CDMA receive IF filter 98 are combined into a single filter having a bandwidth that includes both the GPS and CDMA modulation bandwidths. Further sharing of can be achieved.

As mentioned above, the outputs of narrowband CDMA receive IF filter 98 and narrowband AMPS receive IF filter 99 are also amplified by common IF VGA 100 to generate a common IF information signal 156. Direct combining of the outputs of these filters can be achieved because only one filter will pass the signal at any time, as controlled by the service selection switch 84. However, in another embodiment of the present invention, further sharing of the receiver front end block can be achieved when switchable wideband LNAs and mixers are used that can cover both CDMA and GPS bands. In this embodiment, the parallel LNAs, filters and mixers may be replaced by a single LNA, filter and mixer which may be switchably coupled to the GPS RF information signal 104 or the received RF information signal 44.

The common IF information signal 156 is then mixed with the receiving IF LO 132 and demodulated by the frequency conversion and demodulation electronics 114 in the demodulator 28. Since the IF frequencies of CDMA / analog AMPS and GPS are different, the receiving IF LO 132 used for GPS modulation is not generated by the receiving IF frequency source 124. Instead, the receive IF LO 132 used for GPS demodulation is generated by the GPS IF frequency source 126 in parallel with the receive IF frequency source 124 and by the receive IF loop electronics 128 a reference source ( 58 is phase locked. In a preferred embodiment of the invention, the GPS IF frequency source 126 is a VCO. However, in another embodiment, the GPS IF frequency source 126 may be any adjustable frequency source.

The frequency conversion and demodulation electronics 114 generate a baseband information signal 148. In GPS mode, this baseband information signal 148 includes a GPS baseband signal filtered by the GPS baseband filter 142 to remove pseudo frequencies generated by the frequency conversion and demodulation electronics 114. have. The GPS baseband filter 142 has a bandwidth of approximately 2 MHz to accommodate the modulation bandwidth of the GPS baseband signal, is a low pass filter when the receiving baseband signal is DC, and also when the receiving baseband signal is near DC. May be a band pass filter. The filtered and demodulated signal is then processed by quantizer 118 which generates GPS I and Q outputs 154.

In one embodiment of the invention shown in FIG. 4, full GPS processing is provided by coupling the I and Q outputs 154 of the GPS of the quantizer 118 to the overall GPS processor 144. In a preferred embodiment of the present invention, the entire GPS processor 144 is a Scorpio ^™ device (part number 11577 from Rockwell), incorporated herein by reference.

In another embodiment of the present invention shown in FIG. 5, the E911 support capability is achieved by coupling a Coleman filter 146 between the frequency conversion and demodulation electronics 114 and the GPS baseband filter 142. Is provided. Coliman filter 146 is a subset of the entire GPS processor 144, and band-reduces the I and Q outputs of spread spectrum GPS to include baseband modems [receivers, controllers and all baseband digital signal processors (DSPs). And a matched filter for generating a baseband signal in a format for preparing the baseband to be processed by]. Since the Coliman filter 146 is a subset of the full GPS processor 144, another embodiment of the present invention with both full GPS capability and E911 support requires only the full GPS processor 144 and the Coliman filter. Does not require (146).

Referring again to FIG. 3, in an embodiment of the present invention, the service selector electronic device 120 configures a communication transceiver having GPS capability 48 for either CDMA or GPS operation. In a preferred embodiment of the present invention, the service selector electronic device 120 is a processor programmable by remote command. In another embodiment, the service selector electronic device 120 may include a factory-programmable logic device or user-configurable logic. When the service selector electronics 120 are configured for CDMA operation, the service selector switch 84 is configured to couple the duplexer 82 to the antenna 22, and the receive RF frequency generator 130 is a received RF frequency source. 134 is configured to couple to the receive downconverter mixer 96, and the receive IF frequency generator 122 is configured to couple the receive IF frequency source 124 to the frequency conversion and demodulation electronics 114. The service selector electronic device 120 is configured for GPS operation, the service selector switch 84 is configured to couple the preselector filter 102 to the antenna 22, and the receive RF frequency generator 130 is the RF of the GPS. Is configured to couple the frequency source 138 to the receive downconverter mixer 96 and the receive IF frequency generator 122 is configured to couple the IF frequency source 126 of the GPS to the frequency conversion and demodulation electronics 114. .

Embodiments of the present invention described above, together with separate transmit IF loop electronics 56 and receive IF loop electronics 128, provide a separate transmit IF frequency source 54, receive IF frequency source 124 and GPS. IF frequency source 126 is used. However, in another embodiment of the invention, the receiving IF frequency source 124 and the IF frequency source 126 of the GPS may comprise a common IF frequency source, or in another embodiment, the transmitting IF frequency source. (54), the receive IF frequency source 124 and the IF frequency source 126 of the GPS may include a common IF frequency source, and the transmit IF loop electronics 56 and the receive IF loop electronics 128 are the same. It may include an electronic device. In this embodiment, the service selector electronic device 120 configures the common loop electronic device to generate a desired frequency from a common frequency source.

Embodiments of the present invention described above, together with separate transmit RF loop electronics 72 and receive RF loop electronics 136, provide a separate transmit RF frequency source 70, receive RF frequency source 134 and GPS. RF frequency source 138 is used. However, in another embodiment of the invention, the receiving RF frequency source 134 and the RF frequency source 138 of the GPS may include a common RF frequency source, or in another embodiment, the transmitting RF frequency source. 70, RF loop electronics 72 of receive RF frequency source 134 and GPS may comprise a common RF frequency source, transmit RF loop electronics 72 and receive RF loop electronics 136 It may include the same electronic device. In this embodiment, the service selector electronic device 120 configures the common loop electronic device to generate a desired frequency from a common frequency source.

Although the foregoing discussion focuses on multiservice CDMA / analog AMPS and GPS capabilities, it should be noted that other embodiments of the present invention are scalable to include multiband and multiservice transceivers. For example, with GPS capability, wireless communications that are operable under multiple communication standard schemes such as CDMA and GSM are available. The multi-band transceiver according to another embodiment uses a combination of parallel functional blocks of the RF unit and shared functional blocks of the IF unit.

Thus, according to the foregoing detailed description, preferred embodiments of the present invention share the same frequency source, and multi-band communications that reduce size, weight, complexity, power consumption and cost by filtering between transmitter and receiver and between bands. Provide systems and processes for the unit.

The foregoing detailed description of the preferred embodiment of the present invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. It is intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto.

Accordingly, an embodiment of the present invention is to provide a system and processing method for a composite functional block communication transceiver having an E911 support capability of automatically providing a location of the transceiver when a 911 relief request is made from the transceiver.

Another embodiment of the present invention is to provide a system and processing method for a composite functional block communication transceiver having the highest resolution that GPS can support to provide the location of the transceiver at the operator's request.

Yet another embodiment of the present invention provides a system and processing method for a composite function block communication transceiver with GPS processing that shares a minimum size, weight, complexity, power consumption, and cost frequency source, amplifier, and mixer. will be.

These and other objects are achieved by a communication system capable of communicating RF signals to any one of a plurality of communication standards using a common antenna. The communication system comprises a transmitting unit having at least one transmitting RF information signal output and a receiving unit having at least one receiving RF information signal input and a GPS RF information signal input. The transmission unit is a modulator for modulating a transmission IF as a transmission baseband information signal to generate a transmission IF information signal, and upconverts a transmission IF information signal as a transmission RF to generate at least one transmission RF information signal. It includes an upconverter. The receiving unit down-converts the at least one RF information signal received as the receiving RF to generate the receiving IF information signal, and down converts the GPS RF information signal as the received RF to generate the GPS RF information signal. A GPS downconverter and a demodulator for demodulating the received IF information signal and the GPS IF information signal as a receiving IF to generate GPS and baseband signals. The antenna is used to transmit and receive an RF information signal in combination with at least one transmit RF information signal output, at least one receive RF information signal input, and a GPS RF information signal input.

Claims (34)

A communication system for communicating a first information signal to any one of a plurality of communication standards through a common antenna, A modulator for modulating a transmit second local oscillator (LO) frequency into a transmit baseband information signal to generate a transmit second information signal, and upconverting the transmit second information signal to a transmit first LO frequency to at least one transmit first A transmitting unit having an upconverter for generating an information signal and at least one transmitting first information signal output for communicating at least one transmitting first information signal; A receiving unit having at least one receiving first information signal input for communicating at least one receiving first information signal and a GPS first information signal input for communicating a satellite positioning system (GPS) first information signal, the receiving unit comprising: At least one receiving downconverter for downconverting the received first information signal to the received first LO frequency to generate a received second information signal, and for converting the GPS first information signal to the received first LO frequency for downconversion; A receiving unit having a GPS downconverter for generating a second information signal, and a demodulator for demodulating the received second information signal and the GPS second information signal to a received second LO frequency to generate a GPS and a received baseband signal; An antenna coupled to the at least one transmitting first information signal output, the at least one receiving first information signal input, and a GPS first information signal input to transmit and receive a first information signal. Communication system comprising a The communication system of claim 1, further comprising a GPS processor coupled to receive the GPS baseband signal, the GPS processor comprising a GPS engine to perform GPS processing and acquisition. 2. The system of claim 1, further comprising a Coleman filter coupled to receive the GPS baseband signal, wherein the Coleman filter band-reduces the GPS baseband signal to provide E911 support. And a matched filter. The communication system of claim 1, wherein one of the plurality of communication standards is a code division multiple access (CDMA) scheme. 2. The system of claim 1, wherein the receiving unit further comprises a common second variable gain amplifier coupled to receive the received second information signal and the GPS second information signal, wherein the common second variable gain amplifier comprises the receiver. 2 amplifying and transmitting the information signal and the GPS second information signal to the demodulator, wherein the common second variable gain amplifier has a dynamic range of about 90 dB. 6. The receiver of claim 5, wherein the receiving unit further comprises a GPS first low noise amplifier coupled between the antenna and a GPS downconverter to amplify the GPS first information signal received from the antenna, wherein the GPS first low noise The amplifier has a noise figure of about 1.5 dB and a gain of about 20 dB. 7. The receiver of claim 6, wherein the receiving unit further comprises a first preselector filter coupled between the GPS first low noise amplifier and the antenna for filtering the GPS first information signal received from the antenna, Wherein the selector filter has a passband of about 1574.42 to 1576.42 MHz. 7. The system of claim 6, wherein the receiving unit further comprises a GPS first image blocking filter coupled between the GPS downconverter and the GPS first low noise amplifier to filter the image frequency generated by the GPS first low noise amplifier. Wherein the GPS first image blocking filter has a passband of about 1574.42 to 1576.42 MHz. 6. The GPS receiver of claim 5, wherein the receiving unit comprises a GPS narrowband second filter coupled between a common second variable gain amplifier and the GPS downconverter to filter spurious frequencies generated by the GPS downconverter. Further comprising the GPS narrowband second filter having a bandwidth of about 2 MHz. 2. The apparatus of claim 1, further comprising a common first frequency source for generating the received first LO frequency, wherein the at least one receive down converter converts the at least one received first information signal to the received first LO frequency. Mixing to generate the received second information signal, and wherein the GPS downconverter mixes the GPS first information signal with the received first LO frequency to generate the GPS second information signal. 2. The apparatus of claim 1, further comprising a common second frequency source generating the received second LO frequency, wherein the demodulator mixes the received second information signal with the received second LO frequency to receive the received baseband signal. And generate the GPS baseband signal by mixing the GPS second information signal with the received second LO frequency. 2. The apparatus of claim 1, further comprising a common first frequency source for generating the receive first LO frequency and the transmit first LO frequency, wherein the at least one receive downconverter receives the at least one receive first information signal. Generating a received second information signal by mixing with the received first LO frequency, the GPS downconverter generating the GPS second information signal by mixing the GPS first information signal with the received first LO frequency, and An up-converter mixes the transmit second information signal with the transmit first LO frequency to generate the at least one transmit first information signal. 2. The apparatus of claim 1, further comprising a common second frequency source generating the received second LO frequency and the transmitted second LO frequency, wherein the demodulator mixes the received second information signal and the received second LO frequency. Generate the received baseband signal, and mix the GPS second information signal and the received second LO frequency to generate the GPS baseband signal, wherein the modulator is the transmit baseband information signal and the transmit second LO And mixes frequencies to generate the transmitting second information signal. In the method of communicating the first information signal to any one of a plurality of communication standards via a common antenna, Modulating a transmission second LO frequency into a transmission baseband information signal to generate a transmission second information signal, and upconverting the transmission second information signal to a transmission first LO frequency to generate at least one transmission first information signal; Transmitting the at least one transmitting first information signal via the antenna; Receiving at least one received first information signal from the antenna, down converting the at least one received first information signal to a received first LO frequency to generate a received second information signal, and receiving the received second information signal Demodulating to a second received LO frequency to generate a received baseband information signal; Receiving a GPS first information signal from the antenna, down converting the GPS first information signal to the received first LO frequency to generate a GPS second information signal, and converting the GPS second information signal to the received second LO; Demodulating to a frequency to generate a GPS baseband information signal How to include. 15. The method of claim 14, further comprising: filtering the received baseband signal to remove out-of-band frequencies and quantizing the received baseband signal; Filtering the GPS baseband signal to remove out-of-band frequencies and quantizing the GPS baseband signal. 16. The method of claim 15, prior to filtering the GPS baseband signal to remove out-of-band frequencies, Coliman filtering the GPS baseband signal to band reduce the GPS baseband signal and provide E911 support. The method further comprises the step of filtering. 16. The method of claim 15, further comprising performing GPS processing and acquisition of the quantized GPS baseband signal subsequent to quantizing the GPS baseband signal. A communication system for communicating a first information signal to any one of a plurality of communication standards through a common antenna, Modulating a transmission second LO frequency into a transmission baseband information signal to generate a transmission second information signal, and upconverting the transmission second information signal to a transmission first LO frequency to generate at least one transmission first information signal; Means for transmitting the at least one transmitting first information signal via the antenna; Receiving at least one received first information signal from the antenna, down converting the at least one received first information signal to a received first LO frequency to generate a received second information signal, and receiving the received second information signal Means for demodulating to a received second LO frequency to generate a received baseband information signal; Receiving a GPS first information signal from the antenna, down converting the GPS first information signal to the received first LO frequency to generate a GPS second information signal, and converting the GPS second information signal to the received second LO; Means for demodulating to a frequency to generate a GPS baseband information signal Communication system comprising a. 19. The apparatus of claim 18, further comprising: means for filtering the received baseband signal to remove out-of-band frequencies and quantizing the received baseband signal; Means for filtering the GPS baseband signal to remove out-of-band frequencies and quantizing the GPS baseband signal. 20. The apparatus of claim 19, further comprising means for coli only filtering the GPS baseband signal to band reduce the GPS baseband signal and provide E911 support, wherein the means for filtering coli only the GPS baseband signal comprises: And a means for demodulating a GPS second information signal to the received second LO frequency and means for filtering the GPS baseband signal. 20. The apparatus of claim 19, further comprising means for performing GPS processing and acquisition on the quantized GPS baseband signal, wherein the means for performing GPS processing and acquisition is coupled to quantization means of the GPS baseband signal. Communication system. A receiving unit of a communication system for receiving a first information signal through a common antenna, A first information signal input for receiving the first information signal and a GPS information signal input for receiving a first positioning signal (GPS); A downconverter for downconverting the first information signal according to a received first local oscillator frequency to generate a second information signal; A GPS downconverter for downconverting the GPS information signal in accordance with the received first local oscillator frequency to generate a GPS second information signal; A demodulator that demodulates the second information signal and the GPS second information signal to a received second local oscillator frequency to generate a GPS and receive baseband signal; Receiving device of a communication system comprising a. 2. The receiving unit of claim 1, further comprising a GPS processor for receiving the GPS baseband signal, wherein the GPS processor comprises a GPS engine for performing GPS processing and acquisition. 2. The system of claim 1, further comprising a Coliman filter coupled to receive the GPS baseband signal, wherein the Coliman filter comprises a matched filter for band reducing the GPS baseband signal and providing E911 support. Receiving unit of a communication system. In the method for receiving a first information signal via a common antenna, Receiving a first information signal from the common antenna; Down converting the received first information signal to a received first local oscillator frequency to generate a received second information signal; Demodulating the received second information signal at a received second local oscillator frequency to generate a received baseband information signal; Receiving a GPS first information signal from the antenna; Down converting the GPS first information signal to the received first local oscillator frequency to generate a GPS second information signal; Demodulating the GPS second information signal to the received second local oscillator frequency to generate a GPS baseband information signal How to include. 27. The method of claim 25, further comprising: filtering the received baseband signal to remove out-of-band frequencies and quantizing the received baseband signal; Filtering the GPS baseband signal to remove out-of-band frequencies and quantizing the GPS baseband signal. A communication system for communicating a first information signal to any one of a plurality of communication standards through a common antenna, Receive a first information signal from the common antenna, down convert the received first information signal to a receive first local oscillator frequency to generate a second information signal, and convert the second information signal to a receive second local oscillator frequency. Means for demodulating to generate a received baseband information signal; Receiving a GPS first information signal from the antenna, down converting the GPS first information signal to the received first local oscillator frequency to generate a GPS second information signal, and converting the GPS second information signal to the receiving second Means for generating a GPS baseband information signal by demodulating at a local oscillator frequency Communication system comprising a. 28. The apparatus of claim 27, further comprising: means for filtering the received baseband signal to remove out-of-band frequencies and quantizing the received baseband signal; Means for filtering the GPS baseband signal to remove out-of-band frequencies and quantizing the GPS baseband signal. A modulator for modulating the first local oscillator frequency into a baseband information signal to generate a first information signal; An upconverter which upconverts the first information signal to a second local oscillator frequency to generate a second information signal Transmission unit of a communication system comprising a. 30. The transmission unit of claim 29, wherein the transmission unit transmits the second information signal via a shared antenna shared with a reception unit of a satellite positioning system. 31. The transmission unit of claim 30, wherein the second information signal comprises an information signal in a CDMA format. Means for modulating the first local oscillator frequency into a baseband information signal to generate a first information signal; Means for upconverting the first information signal to a second local oscillator frequency to generate a second information signal; Means for outputting the second information signal Transmission unit of a communication system comprising a. 33. The transmission unit of claim 32, wherein the second information signal conforms to a CDMA standard. 34. The transmission unit of claim 33, wherein the output means comprises a shared antenna shared with a satellite positioning system.