KR20110094281A - Bandwith conditioning device - Google Patents

Abstract

An apparatus for adjusting the overall bandwidth is provided. The apparatus includes a return path extending at least a portion of the distance between the supplier side connector and the user side connector, and a forward path extending at least a portion of the distance between the supplier side connector and the user side connector. An upstream section includes a variable signal level adjuster coupled within the return path. A downstream section includes a forward coupler connected within the forward path. The apparatus further includes one or more microprocessors. The microprocessor is electrically connected upstream of the variable signal level adjustment device. The microprocessor reduces the amount of signal level adjustment applied to the return path in response to the reduction of the downstream bandwidth level at the forward coupler.

Description

Bandwidth Adjuster {BANDWITH CONDITIONING DEVICE}

The present invention is directed to a signal conditioning apparatus for use in a joint listening antenna TV ("CATV") system.

The use of CATV to provide the Internet, Internet protocols as well as voice ("VOIP"), telephone, television, security, and music services is well known in the art. In providing these services, the downstream bandwidth (ie, radio frequency signal ("RF"), digital signal and / or optical signal) is sent from the service provider to the user, and the upstream bandwidth (ie, radio frequency (" RF ") signals, digital signals and / or optical signals) are sent from the user to the supplier. The distance between the supplier and the user will in most cases make the bandwidth of the downstream and upstream bandwidth the total bandwidth passed through a signal transmission, such as a coaxial cable. For example, the downstream bandwidth is a signal having a relatively high frequency within the total bandwidth of the CATV system, and the upstream bandwidth is a signal having a relatively low frequency.

Traditionally, the CATV system includes head end equipment, and the downstream bandwidth begins into the main CATV distributed system, where the system includes a plurality of trunk lines, each serving one or more local distributed networks. The upstream bandwidth is then sent to a relatively small number of users (eg, about 100-500) associated with a particular local distributed network. Devices, such as high pass filters, are located in various locations within the CATV system to direct the orderly flow of trunk lines of downstream bandwidth from the head end equipment through the trunk line, through the local distributed network, and ultimately to the user. To ensure.

At various locations between the head end equipment and the user, there are amplifiers and slope adjusters for the purpose of maintaining the quality of the downstream bandwidth. This introduces three items (ie quality, amplifier and slope adjuster), which are important in the following description. These devices are described broadly below.

The quality of the downstream bandwidth is: (i) the signal level (hereinafter referred to as "level") of a particular channel in the downstream bandwidth; And (ii) a measure of the consistency (hereinafter referred to as "slope") of all channels in the downstream bandwidth. These objective measurements are often used by technicians, analysts and / or other devices to help evaluate CATV system performance during operation and to adjust customer complaints.

The level of each channel is within a certain range determined to provide satisfactory video, sound and information delivery for the user. Although the specific needs and targets for each channel vary in multiple CATV systems and even in a single CATV system, it should be understood that there is a specific target for each level of the channel. This is the simplest definition for describing "levels", which does not include other changes, such as between a channel with an analog conversion format and a channel with a digital change format.

The slope is mainly used to evaluate the amount of loss experienced due to the length of the signal transmission line with downstream bandwidth. All channels in the downstream bandwidth experience some loss, and channels transmitted using higher frequencies in the downstream bandwidth experience more losses than those transmitted using lower frequencies. Thus, when graphed such that levels for all channels in the downstream bandwidth are arranged in order according to the frequency range of each channel, there is a significant visible downstream slope in the graph from the lowest frequency channel to the highest frequency channel. Will be. This downstream slope is more pronounced when the length of the signal transmission line increases. This is the simplest definition for describing a consistent level across all channels and slopes caused by losses in the signal transmission line. This definition does not include other changes in the level, such as between a channel having an analog modulation format and a channel having a digital modulation format.

The presence of the slope is not eliminated through the use of typical drop-style amplifiers. The drop-style amplifier only amplifies the entire downstream bandwidth. In other words, these drop-style amplifiers raise the level of each channel equally. Next, if there is a large amount of slope, such as when the user's residence includes a long signal transmission distance, the drop-style amplifier will exceed their level requirement or target while other channels are below these requirements or targets. To help.

It is known to add a fixed or manually adjustable slope compensator / low frequency attenuator when the signal transmission line is long. However, these devices require expensive inspection devices to determine how much slope compensation should be supplied to a particular area or whether such a supply should be available. In addition, due to installation costs and comprehensive misunderstandings regarding how to install such services, there are few practical uses of such devices compared to the required number. In addition to this problem experienced with the downstream bandwidth, the upstream bandwidth is conditioned to ensure customer satisfaction.

The upstream bandwidth passing through each of the local distribution networks is a combination of upstream bandwidths generated within each region of a user connected to the particular distribution network. The upstream bandwidth generated within each region includes desirable upstream information such as from modems, set top boxes and other desirable signals. The upstream bandwidth generated within each user premise includes undesirable interference signals such as noise or other false signals. Many such undesirable interference generators are electrical devices that inadvertently generate electrical signals as a result of these operations. These devices are vacuum cleaners, electric motors, household transformers, welders and many other household electrical devices. Many other generators of such undesirable interference signals include devices that intentionally generate RF signals as part of their operation. These devices include wireless home or office telephones, cell phones, wireless Internet devices, citizen band (“CB”) radios, personal communication devices, and the like. The RF generated by these devices is desirable for their intended purpose, but will conflict with the desired upstream information if they are allowed to enter the CATV system.

Undesirable interfering signals are either accidentally generated electrical signals or intentionally generated RF signals, or they enter the CATV system through ports other than terminals, malfunctioning devices, damaged coaxial cables and / or damaged splitters. As described above, the downstream / upstream bandwidth is passed through some kind of signal transmission line, coaxial cable at most of the distance between the user and the head end. The coaxial cable is intentionally shielded from undesirable interference signals by a conductive layer located radially outwardly of the central conductor and coaxially with the central conductor. Similarly, devices connected to coaxial cables allow shielding of unwanted interference signals. However, if there is no device connected to the port or no additional coaxial cable, such as an unused electrical port in the room in your area, the center conductor of such a port may be undesirable in such a room. It is exposed to interference signals and acts like a small antenna to collect undesirable interference signals. Similarly, devices or coaxial cables with damaged or malfunctioning shields can also collect undesirable interference signals.

Undesired interfering signals place additional strain on the CATV system upstream bandwidth portion. When a user uploads a large image file to a photo sharing website, such image file can be bundled into multiple data packets, which are upstream bandwidth by another user located on a particular signal transmission line within the CATV system. It can be mixed with other data packets passing through a specific part of. In order to optimize the overall data throughput over a particular signal transmission line, the data packets can be greatly delayed or reconstructed without the user's knowledge and without the user's knowledge. When a user uses a VOIP telephone service, these voices are formally similar to the data packets used to upload video files. Since the conversation is usually performed in real time, a continuous and unbroken flow of data packets is required, and the delivery of the data packet and / or the reconstruction (organization) of the data packet causes audio distortion of the user's voice. The delay and reconfiguration of uploading data packets with such VOIP telephony service is measured in terms of whether jitter is generated because of the significant quality of service features it provides. Undesired interfering signals frequently damage, move and / or destroy individual data packets, which easily introduces additional jitter.

In view of the above description, it will be appreciated that there are unique and system-wide problems, and they will understand that upstream bandwidth is open and easily affected by any single user. For example, although downstream bandwidth may be constantly monitored and serviced by experienced network engineers, the upstream bandwidth is maintained by the user without the necessary skills and knowledge to reduce the generation and passing of interfering signals into the upstream bandwidth. . This problem becomes even worse if one user can easily affect all other users, and the number of users connected together in a particular distributed network is even worse.

Efforts to improve the overall signal quality of upstream bandwidth have not been successful in conventional methods. Measurements for overall signal quality include components such as signal strength and signal to noise ratio (ie, necessary information signal to unnecessary interference signal ratio). As described above, increasing the downstream bandwidth strength has been achieved by a drop-style amplifier used in or near a particular user area. The success of such drop-style amplifiers is because very low levels of unwanted interference signals exist in the downstream bandwidth for the reasons described above. The unique presence of unwanted interference signals in the upstream bandwidth generated by each user eliminates the use of these representative, drop-style amplifiers to amplify the upstream bandwidth since the unwanted interference signal is amplified to the same size as the required information signal. Has been made. Thus, the signal-to-noise ratio is nearly constant or even worse when such a representative drop-style amplifier is used so that the overall signal quality of the upstream bandwidth is not improved. One attempt to solve these problems with upstream bandwidth is to increase the width of the upstream bandwidth to accommodate more information to accommodate more information, so that the upstream bandwidth is less affected by unwanted interference signals. It is. Traditionally, the size of the downstream bandwidth far exceeds that of the upstream bandwidth due to the nature of the services provided. For example, the downstream bandwidth must accommodate both television and music programs, including the Internet and VOIP downloading, while the upstream bandwidth only has to accommodate internet uploading, system control signals, and VOIP uploading.

Several CATV providers have plans to increase the width of the upstream bandwidth from 5-42 MHz to 5-85 MHz to allow for more flow of upstream content. In addition to this increase in bandwidth, the downstream bandwidth must be reduced in size as the overall bandwidth must be relatively fixed. However, such a change is very difficult to implement.

Typical implementations require that all drop-style amplifiers and bidirectional (deplex) filters in the network amplifier and nodes of the CATV system be modified as part of increasing the upstream bandwidth magnitude. Regarding the difficulty of making such changes, all changes must be made at various locations through the CATV system at a single specific time. Thus, such an implementation is time consuming, expensive, and not easy to combine.

In addition, increasing the size of the upstream bandwidth allows providers to push their downstream content to higher and higher frequencies of downstream bandwidth. As described above, these high frequencies are much more sensitive to parasitic losses in signal strength generated by signal transmission lines, connectors in the user area, devices connected to the signal transmission line in the user area, and the like. Thus, as a result of increasing the size of the upstream bandwidth, the quality of content moved to higher frequencies within the downstream bandwidth is greatly reduced, resulting in a decrease in customer satisfaction and an increase in costly service calls.

Increasing the upstream bandwidth size also increases the flow of upstream data packets, and upstream bandwidth is a dependency / congestion problem due to unique and system-wide issues that make upstream bandwidth open and easily affected by any single user. Be sensitive to

For at least the reasons described above, there is a need for an apparatus that can provide the ability to increase the overall quality of the downstream bandwidth, increase the overall quality of the upstream bandwidth, and / or to expand its breadth of the upstream bandwidth.

According to one embodiment of the present invention, there is provided an upstream bandwidth adjustment apparatus that can be inserted into a signal transmission line of a CATV system near or adjacent to an area of a user.

Such apparatus includes a variable signal level adjusting device configured to generate a signal level adjusting amount for an upstream bandwidth;

A signal measuring circuit configured to measure a second signal strength after applying the first signal strength value of the upstream bandwidth and the additional signal level adjustment amount before applying the additional signal level adjustment increment; And

circuitry configured to (i) compare the first signal strength with the second signal strength, and (ii) remove at least a portion of the additional signal level adjustment increment when the first signal strength is greater than the second signal strength.

According to one embodiment of the present invention, a method is provided for adjusting upstream bandwidth transmitted over a CATV system transmission line using a device located in, near, or in proximity to a user's area. The method comprises (a) providing a device having a user side and a provider side; (b) providing a variable signal level adjusting device between the user side and the supplier side; (c) measuring a first signal strength value of the upstream bandwidth at an upstream location from the variable signal level adjuster; (d) apply additional signal level adjustment increments to the upstream bandwidth; (e) measuring a second signal strength value; (f) compare the first signal strength value with the second signal strength value; (g) repeating steps (c) to (f) for a predetermined number of periods. Part of the additional level adjustment increment is removed when the second signal level value is less than the first signal level value.

According to one embodiment of the present invention, a method is provided for adjusting upstream bandwidth transmitted over a CATV system transmission line using a device located in, near, or in proximity to a user's area. The method comprises (a) providing a device having a user side and a provider side; (b) providing a variable signal level adjusting device between the user side and the supplier side; (c) measuring a first signal strength value of the upstream bandwidth at an upstream location from the variable signal level adjuster; (d) apply additional signal level adjustment increments to the upstream bandwidth; (e) measure a second signal strength value after the signal level adjustment additional amount has been applied; (f) compare the first signal strength value with the second signal strength value; (g) proceeding to step (i) when the second signal strength value is less than the first signal strength value; (h) repeating steps (c) to (g) for a predetermined number of periods, and proceeding to step (j) when the predetermined number of periods are finished; (i) reduce the additional signal level adjustment increment by a predetermined amount and proceed to step (j); And (j) providing continued signal level adjustment for the upstream bandwidth.

According to one embodiment of the present invention, there is provided a downstream bandwidth output level and / or output level slope compensation device that can be inserted into a CATV system transmission line in, near, or in proximity to a user's area. The apparatus includes a tuner configured to scan downstream bandwidth to identify low and high frequency channels; And a channel analyzer configured to determine the format of each of the low and high frequency channels. The apparatus also includes a signal level measuring device configured to measure the low frequency channel level and the high frequency channel level. The apparatus of the present invention also provides for (i) adding an offset value to the low frequency channel level when the low frequency channel is in digital format, and (ii) subtracting an offset value from the low frequency channel level when the low frequency channel is in analog format, (iii) adding an offset value to the high frequency channel level when the high frequency channel is in digital format, and (iv) subtracting a gain offset value from the high frequency channel level when the high frequency channel is in analog format. It further includes an offset circuit configured to perform one or more steps. The apparatus also includes a microprocessor configured to compare the low frequency channel level and the high frequency channel level, including offset values, with a predetermined signal strength gain / loss curve. The apparatus further includes a variable output level compensation device for providing an output level compensation amount at the downstream bandwidth, and a variable slope adjustment circuit for providing a slope adjustment amount at the downstream bandwidth.

In accordance with one embodiment of the present invention, a method is provided for adjusting downstream bandwidth in proximity to or near a CATV service user area. The method includes receiving downstream bandwidth from a CATV provider; Scan the downstream bandwidth to obtain a low frequency channel and a high frequency channel; And measuring the low frequency channel level of the low frequency channel and the high frequency channel level of the high frequency channel. The method also determines a low frequency channel modulation format; Determine a high frequency channel modulation format; And one of the low frequency channel level and the high frequency channel level with a predetermined offset when one channel among the low frequency channel and the high frequency channel is an analog modulation format and one channel among the low frequency channel and the high frequency channel is a digital modulation format. Offsetting. The method also compares the low frequency channel level and the high frequency channel level, including the offset value, with a predetermined signal strength / gain / loss curve. The method of the present invention also provides an output level compensation amount at the downstream bandwidth; And providing slope adjustment with downstream bandwidth.

According to one embodiment of the present invention, there is provided a frequency band selection apparatus that can be inserted into a signal transmission line of a CATV system in, near, or in proximity to a user's area. The device includes at least two sets of signal paths coming between the provider side and the user side. Each set of signal paths includes two discrete signal paths, a forward path allows downstream bandwidth to pass from the provider side to the user side, and a return path allows upstream bandwidth to pass from the user side to the provider side. The forward path and the return path are separated by different blocking transmission frequencies for each set of signal paths. The apparatus of the invention also has at least two discrete switch positions, the switch controller selecting the switch positions as a result of the information signal. Each switch position corresponds to a set of signal paths.

According to one embodiment of the invention, a method is provided for changing a CATV frequency band in, near, or in proximity to a CATV service user area. The method of the present invention provides frequency band selection in, near, or in proximity to a user area. The apparatus includes at least two sets of signal paths coming between a supplier side and a user side of a frequency band selector. Each set of signal paths includes two discrete signal paths, a forward path allows downstream bandwidth to pass from the provider side to the user side, and a return path allows upstream bandwidth to pass from the user side to the provider side. The forward path and the return path are separated by different blocking transmission frequencies for each set of signal paths. The apparatus also includes a switch controller having at least two discrete switch positions. The switch controller selects the switch position as a result of the information signal. Each switch position corresponds to a set of signal paths. The method also includes actuating the switch controller as a result of the information signal.

According to one embodiment of the invention, there is provided a downstream bandwidth adjuster that can be inserted into a transmission line of a CATV system in and near the user's area. The apparatus includes a forward path extending over at least a portion of the distance between the supplier side connector and the user side connector. Couplers are coupled within the forward path and provide a secondary path. A tuner coupled to the coupler is tunable based on an input from a microprocessor, the tuner providing a tuner output of a selected channel, wherein the selected channel is at least one of a high frequency channel and a low frequency channel. . A channel analyzer is connected to the output of the tuner. The channel analyzer provides a modulation output to a microprocessor and the modulation format output is different when the selected channel is analog modulation and when the selected channel is digital modulation. A slope adjustment circuit is connected in the forward path between the coupler and the supplier side connector. The slope adjuster is adjustable based on the slope control output provided by the microprocessor. An output compensation circuit is electrically connected in the forward signal path between the coupler and the supplier side connector. The output compensation device is adjustable based on the level control output from the microprocessor.

In accordance with one embodiment of the present invention, a method is provided for adjusting downstream bandwidth in or near a CATV service user area. The method includes starting the first mode. The first mode is: tune to an initial high frequency channel from the downstream bandwidth; And high channel modulation and high channel level from the initial high frequency channel. The method also tunes to an initial low frequency channel from the downstream bandwidth; And obtain a low channel modulation format and a low channel level from the initial low frequency channel. The method also includes providing a level adjustment amount of the downstream bandwidth, and a slope adjustment amount of the downstream bandwidth.

According to one embodiment of the invention, an apparatus for adjusting the overall bandwidth is provided. The apparatus includes a return path extending at least a portion of the distance between a supplier side connector and a user side connector; And a forward path extending at least a portion of the distance between the supplier side connector and the user side connector. The upstream section includes a variable signal level adjuster coupled within the return path. The downstream section includes a forward coupler connected within the forward path. The apparatus also includes at least one microprocessor. The microprocessor is electrically connected upstream (upstream) of the variable signal level adjustment device. The microprocessor reduces the amount of signal level adjustment applied to the return path in response to the reduction of the downstream bandwidth level in the forward coupler.

In accordance with one embodiment of the present invention, a method for adjusting upstream bandwidth is provided. The method includes adding one or more attenuation increments to the upstream bandwidth. The method also includes measuring a first level of downstream bandwidth. The method also includes removing at least one or more attenuation increments in response to the first level of downstream bandwidth.

According to one embodiment of the invention, a measuring apparatus for measuring downstream bandwidth is provided. The apparatus includes a return path extending at least a portion of the distance between the supplier side connector and the user side connector. A coupler is connected in the return path, which coupler provides a secondary path. A detection circuit is electrically connected downstream (downstream) of the coupler. A level detector is electrically connected downstream of the detection circuit and a microprocessor is electrically connected downstream of the level detector. The microprocessor includes a first buffer and a second buffer.

According to one embodiment of the invention, a method for obtaining level data for upstream bandwidth is provided. The method includes converting the frequency dependent voltage flow into a time dependent voltage flow comprising an increased voltage period. The method includes amplifying and maintaining a period of increased voltage using a low pass amplifier and a peak detector. The method records peak values from multiple voltage series in the output voltage flow, each series starts with a measured voltage level above the high voltage limit, and ends with a measured voltage level that passes below the low voltage limit. do. The method also includes locating a peak value in the first buffer and periodically calculating a first buffer average that is an average of the peak values in the first buffer. The method also includes placing each of the first buffer averages in the second buffer and periodically calculating the second buffer averages. The method also includes a technician outputting one or more of the first and second buffer averages of the output device for storage, review, or analysis for the purpose of adjusting the upstream bandwidth.

According to one embodiment of the present invention, an apparatus for adjusting upstream bandwidth is provided. The apparatus includes a return path extending at least a portion of the distance between the supplier side connector and the user side connector, and a coupler coupled within the return path to provide a second path. A detection circuit is electrically connected downstream of the coupler and a level detector is electrically connected downstream of the detection circuit. A microprocessor is electrically connected downstream of the level detector. The microprocessor includes a first buffer and a second buffer. A variable signal level adjuster is electrically connected in the upstream return path from the coupler. The variable signal level adjusting device is controlled by a microprocessor.

According to another embodiment of the present invention, a method for adjusting upstream bandwidth is provided. The method includes converting the frequency dependent voltage flow into a time dependent voltage flow comprising an increased voltage period, and using a low pass amplifier and a peak detector to amplify and maintain the period of increased voltage. The method also records peak values from multiple voltage series in the output voltage flow, each series beginning with a measured voltage level above the high voltage limit, and with a measured voltage level passing below the low voltage limit. It ends.

The method includes placing the peak value in the first buffer and periodically calculating the first buffer average. The method also locates each of the first buffer averages in a second buffer, and wherein the first buffer mean is one of a range above and below a predetermined value range, the range of first buffer averages being within a second buffer (+ ) It is either one of the upper variable amount and the (-) lower variable amount.

The method also includes adding an attenuation increment for the upstream bandwidth when the first buffer is greater than the predetermined value range, and reducing the attenuation increment for the upstream bandwidth when the first buffer is less than the predetermined value range.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram of a CATV system made in accordance with an embodiment of the present invention;
2 is a schematic diagram of a user area (home, etc.) in accordance with an embodiment of the present invention;
FIG. 3 is a circuit diagram illustrating an adjustment apparatus including an upstream section according to an embodiment of the present invention, in dotted lines indicating locations for optional sections, such as the downstream section provided in FIG. 18;
4 is a circuit diagram showing a coupler used in an adjustment device made in accordance with one embodiment of the present invention;
5 is a circuit diagram showing a high pass filter used in an adjusting device made in accordance with one embodiment of the present invention;
6 is a circuit diagram showing an RF detection circuit used in an adjusting device made in accordance with one embodiment of the present invention;
7 is a circuit diagram showing a level detector used in an adjustment device made in accordance with one embodiment of the present invention;
8 is a graph showing the voltage flow from an RF detector to a low pass amplifier in an RF detection circuit used in an adjustment device made in accordance with one embodiment of the present invention;
9 is a graph showing the voltage flow from a low pass amplifier in an RF detection circuit to a level detector used in an adjustment device made in accordance with one embodiment of the present invention;
10 is a graph showing the voltage flow from a level detector to a nonlinear amplifier used in a local (home, etc.) device made in accordance with one embodiment of the present invention;
11 is a circuit diagram of a nonlinear amplifier used in an adjusting device made in accordance with one embodiment of the present invention;
12 is a theoretical response graph of a nonlinear amplifier in response to a linearly increasing voltage.
FIG. 13 graphically illustrates the voltage flow from a nonlinear amplifier to a microprocessor used in an adjustment device made in accordance with one embodiment of the present invention;
FIG. 14 is a flow diagram illustrating an upstream bandwidth adjustment routine performed by a microprocessor used in an adjustment device made in accordance with one embodiment of the present invention. FIG.
15 is a circuit diagram including an upstream section made in accordance with one embodiment of the present invention, wherein a dashed line shows a circuit diagram showing the location of an optional downstream section, such as the downstream section shown in FIG. 18;
FIG. 16 is a circuit diagram illustrating an adjusting device including an upstream section made in accordance with an embodiment of the present invention, wherein a dotted line shows a location of an optional downstream section, such as the downstream section shown in FIG. 18; FIG.
FIG. 17 is a flow diagram illustrating an upstream bandwidth adjustment routine performed by a microprocessor used in a coordination device made in accordance with one embodiment of the present invention. FIG.
FIG. 18 is a circuit diagram illustrating an adjusting device including a downstream section made in accordance with an embodiment of the present invention, wherein the dotted line is optional, such as any of the upstream sections shown in any of FIGS. 3, 15 and 16. A diagram showing upstream section position;
19 is a flow chart showing a signal level measurement routine performed by a microprocessor used in an adjustment device made in accordance with the present invention;
20 is a flow chart showing a signal level measurement routine performed by a microprocessor used in an adjustment device made in accordance with one embodiment of the present invention;
21 graphically illustrates the level curve of downstream bandwidth prior to level adjustment and slope adjustment;
FIG. 22 graphically illustrates level curves for downstream bandwidth after level adjustment and before slope adjustment;
FIG. 23 graphically shows level curves for downstream bandwidth after level adjustment and after slope adjustment, wherein the slope adjustment eventually results in a constant dBmV level curve;
FIG. 24 graphically illustrates the level curve for downstream bandwidth after level adjustment and after slope adjustment, wherein the slope adjustment eventually results in an up slope of 2 dBmV at 54 MHz to 1000 MHz.
25 is a flow diagram illustrating an attenuation reduction routine performed by a microprocessor used in an adjustment device made in accordance with one embodiment of the present invention;
FIG. 26 is a circuit diagram illustrating a frequency band selector optionally including any of the upstream sections shown in FIGS. 3, 15 and 16 and optionally including the downstream section shown in FIG.

As shown in FIG. 1, the CATV system transmits a downstream bandwidth, such as an RF signal, a digital signal, or an optical signal, to the user through the main distribution system 30, and the RF signal, the digital signal, or the optical signal. A provider 20 that receives the same upstream bandwidth from the user through the same main signal distribution system 30 from the user. Tab 90 is located in main signal distribution system 30 to allow the upstream / downstream bandwidth to pass into / from the main signal distribution system 30. A drop transmission line 120 is then used to connect the tab 90 to the houses 10, 60, apartment buildings 50, 70, the coffee shop 80, and the like. As shown in FIG. 1, the overall bandwidth coordinator 100 (“coordinator 100”) of the present invention is connected in series between the drop transmission line 120 and the user area distribution system 130.

The adjuster 100 is positioned such that the "supplier side" of the adjuster 100 is closer to the tab 90 than the "user side" of the adjuster 100. In addition, the adjuster 100 is positioned such that the "user side" of the adjuster 100 is located closer to the user's local distribution system 130 than the "supplier side" of the adjuster 100. Is determined.

In FIG. 1, the adjuster 100 is located at any one position between the tab 90 and the user area distribution system 130. Such a location may be located in or near the user area (eg, home 60, apartment building 50, etc.). The coordination device 100 may be located at any location where CATV services, including Internet services, VOIP services, or other unidirectional / bidirectional services, such as coffee shop 80 or other business locations are used.

As shown in FIG. 2, the user area distribution system 130 is distributed using a splitter 190 such that downstream / upstream bandwidth is routed to the television 150 and the modem 140 according to techniques well known in the art. Allow to pass from / The modem 140 may also include a router that enables Internet services, such as desktop computer 160 and laptop computer 180.

It is also common practice to provide a set top box ("STB") or set top unit ("STU") for direct use with a television. However, in FIG. 2, for convenience of description, the STB or the STU is not included. The STBs and STUs allow many STBs and STU models to use upstream bandwidth to transmit information regarding "pay-per-view" purchases, billing, usage, and interactions with other users, All of these require information to be sent from the STB or STU to the provider 20. In addition, FIG. 2 shows that there is only one coordinator 100 for a premise device (i.e., modem 140), but each coordinator 100 is preferably upstream through an upstream bandwidth. It may be used with two or more local devices (e.g., modems, STBs, STUs, or designated VOIP servers) that carry information signals.

The term "local device" is used to describe one or more of the various devices generating the desired portion of the upstream bandwidth. In particular, the " local device " may be located in a user area that communicates with the provider 20, for example by receiving downstream bandwidth, transmitting information to the provider 20 via the upstream bandwidth, or both. It is used to describe a device located adjacent to the user area. These local devices may include Internet access modems, STBs, STUs, televisions, local security monitoring devices, and any device that needs to report or otherwise provide such information via upstream bandwidth.

In addition, although not shown in FIG. 2, there may be two or more adjusters 100 located in a single area, near, or in close proximity to the same area. For example, there may be an adjusting device 100 located between the modem 140 and the splitter 190 and another adjusting device 100 located between the splitter 190 and the STB or STU in the television 150. Can be. Similarly, coordinator 100 may be located at any point in regional distribution system 130, where upstream bandwidth is passed (eg, from a modem, STB, STU, VOIP server, etc.).

Also, although not shown in FIG. 2, when there is one drop transmission line 120 used to connect the tab 90 to two (or more) user areas, the two (or more) user areas There may be one adjuster 100 in close proximity. Although such an arrangement may not be ideal because the upstream bandwidth from two (or more) users can be consolidated before physically coordinating the coordinator 100, the two or more regions are separated. Such arrangements may be necessary when they are too close to each other to be positioned as

The purpose of placing the coordinator at one of the locations described above is to increase the signal-to-noise ratio of the upstream bandwidth leaving the user's region before the upstream bandwidth of a particular user is integrated with the transmission of another user. To improve the overall quality of the upstream bandwidth in the main distribution system 30. As explained above, amplifying the upstream bandwidth alone cannot achieve the desired result, since the undesirable signal present in the upstream bandwidth is also amplified.

3, the description of the adjusting device 100 is divided into four titles. (i) a generic component; (ii) an optional upstream section 105; (iii) an optional downstream section 108; (iv) interaction between upstream section 105 and downstream section 108; And (v) frequency band selector.

General components are first described and summarized throughout the terminology, to explain how upstream bandwidth can be passed to upstream section 105 and how downstream bandwidth can be passed to downstream section 108. do. The upstream section 105, downstream section 108, and frequency band selector will be described in terms of hardware, operation, and control.

(i) general components

3, the adjuster 100 includes a user side connector 210 and a supplier side connector 215. Each of these connectors 210 and 215 are connectors used in the art to connect signal cables to devices. For example, each of the user side connector 210 and the supplier side connector 215 may be a conventional female "F-type" connector.

A user side surge protector 220 and a supplier side surge protector 225 are provided in electrical proximity to the user side connector 210 and the supplier side connector 215, respectively. This positioning of the surge protectors 220, 225 allows to protect electrically fragile components (described in more detail below) that may be located between the surge protectors 220, 225. Each of the user side surge protector 220 and the supplier side surge protector 225 may be a surge protector known in the electronic application art.

Each of the user side switch 250 and the supplier side switch 255 have two positions. First, in the default position (shown in FIG. 3), the switches 250 and 255 pass signals through the bypass path 230. In the second position, the user side switch 250 and the supplier side switch 255 connect the user side connector 210 to the user side main path 240 and the supplier side connector 215 to the supplier side main path ( 242). As will be described further below, the main components of the adjuster 100 are electrically connected in series between the user side main path 240 and the supplier side main path 242.

The switches 250 and 255 allow the entire bandwidth to pass through the bypass path 230 in the event of a failure in the regulator 100, such as an electrical power failure. The switches 250 and 255 may be a single pole double throw (SPDT) switch known in the art. For example, switches 250 and 255 are selected and installed to automatically select the first non- default position to pass the full bandwidth through the bypass path 230 when no electrical power is present in the regulator 100. . Conversely, when electrical power is present, the switches 250 and 255 move toward the second position, allowing the entire bandwidth to pass through the main paths 240 and 242. When there is an electrical short in the regulator 100, the short will generate an additional current flow that will ultimately result in the destruction of the fuse or the opening of the circuit breaker type device (not shown). Thus, such a short circuit will result in power loss to the switch, allowing the entire bandwidth to pass through the bypass path 230.

Microprocessor 310 (described in detail below) also switches switches 250 and 255 to their first position (ie, bypass path 230 when a failure other than electrical power loss is detected within regulator 100). It is used to operate Although a circuit for such a connection is shown in FIG. 3, the adjustment by the microprocessor 310 can be carried out in addition to the automatic adjustment switches 250 and 255 described above, in which the electrical fault is present. If present, there is automatic positioning for switches 250 and 255.

As used herein, the term “microprocessor” includes any circuit in use capable of performing the functions described herein. For example, the microprocessor 310 may be replaced with a microcontroller, a system specific digital controller, or a composite analog circuit.

The bypass path 230 may be a coaxial cable, an unprotected electrical line, or a metal trace on a circuit board. All these choices can pass the full bandwidth with little signal attenuation.

The user side deplexer 260 and the supplier side deplexer 265 are electrically connected to the user side main path 240 and the supplier side main path 242, respectively. The deplexers 260, 265 are configured to generate a forward path 244 and a return path 246, 248 therebetween. Each of the deplexers 260, 265 acts as a splitter, a high pass filter, and a low pass filter combination, which splits each main path 240, 242 into two signal paths, a low pass filter and a high pass filter, respectively. Split into one path. Using this combination of conditions, each of the high pass filters passes downstream bandwidth, and each of the low pass filters passes upstream bandwidth. In an embodiment of the invention, the downstream bandwidth passes along a forward path 244 between the deplexers 260 and 265, and the upstream bandwidth passes through a return path 246 between the deplexers 260 and 265. 248).

( ii ) Upstream  section

In order to set the steps for the following description, the hardware, operation, and upstream section 105 will first be described in detail. The upstream section 105 selectively attenuates the upstream bandwidth in a certain amount, where a typical local device increases the power and takes up that portion of the upstream bandwidth (ie, desired upstream bandwidth) to compensate for the added attenuation. To transmit. The result will be a percentage greater than the remaining portion of the desired upstream bandwidth (ie, undesirable upstream bandwidth). To achieve this goal, upstream section 105 accurately measures the desired upstream bandwidth level. Such accurate measurement allows the local device to add too much attenuation so that it can no longer compensate for the increase in attenuation by increasing its output power, but rather increase the amount of attenuation.

The desired upstream bandwidth is difficult to measure because of the inherent functional characteristics of the local device. For example, a local device usually transmits the desired upstream bandwidth only when such a local device is requested to transmit information. For example, a local device, such as an internet access modem, only transmits information when the user sends it to the Internet. Since there is no way to predict when such information is sent, the desired upstream bandwidth generated by the local device should be assumed to be time independent and time discontinuous. In addition, the continuity of the information transmitted varies greatly, such as between a simple pay-per-view purchase request and an internet upload of large, detailed photos. In other words, the portion of the upstream bandwidth generated by the local device may be generated at any time and may occur for any length of time.

The upstream section 105 includes a coupler 340 coupled within the return paths 246 and 248, and upstream section through the secondary path propagated from the coupler output 342 to a portion of the upstream bandwidth in terms of power and / or frequency range. Pass it through the device behind me. Those skilled in the art will readily understand which type of coupler is suitable for the purposes of the present invention, in accordance with the present invention and upon specific installation size requests. For example, simple resistors, power dividers, bidirectional couplers, or splitters can be used with careful consideration of the effect of these choices on the characteristic impedance of regulator 100. Individual components present in one embodiment of the coupler 340 are shown in FIG. 4.

The term "connected" is used to mean that the current, voltage, or light is selectively or electrically positioned to pass between the connected components. The term "connected" does not exclude the possibility for a component or devices that come in between the connected components. For example, although the high pass filter 350 is shown positioned in the middle of the relationship between the coupler 340 and the RF amplifier, the coupler 340 may be connected to the RF amplifier 365.

The terms “electrically connected downstream” and “electrically connected upstream” are used to describe where or how the two components are connected. As an example, when the second device is electrically downstream from the first device, the second device receives a signal from the first device. This same configuration could likewise be described for the first device being electrically upstream from the second device.

In FIG. 3, high pass filter 350 is electrically connected downstream from coupler 340, such that coupler output 342 is electrically connected to high pass filter input 352 (FIG. 5). The high pass filter 350 allows only a portion of the upstream bandwidth to pass through the high pass filter output 354 to the remaining devices, described below (FIG. 5), in the embodiment of the present invention. Although high pass filter 350 is not necessary in all cases, it may be beneficial to attenuate upstream bandwidth segments that are known to not have the desired upstream bandwidth. For example, if the local device is known to provide the desired upstream bandwidth in the upstream bandwidth specific segment, it may be beneficial to configure the high pass filter 350 to attenuate the segment of the upstream bandwidth below the upstream bandwidth specific segment transmitted by the local device. Do. Those skilled in the art will readily understand which type of high pass filter is suitable for the purposes of the present invention, in accordance with the present invention and upon specific installation size requirements. The individual components present in one embodiment of the high pass filter 350 are shown in FIG. 5.

RF detection circuitry 360 is electrically connected downstream from the high pass filter 350 such that the high pass filter output 354 is electrically connected to an RF detector input 362 (FIG. 6). RF detector circuit 360 includes an RF amplifier 365, an RF detector 366, and a low pass amplifier 367. The RF amplifier 365 amplifies the downstream bandwidth portion passed through the high pass filter 350 to prepare an RF detector 366. The RF detector 366 can act as an inverse Laplace transform, which is an integral change that is widely used to convert portions of the downstream bandwidth from a frequency domain voltage flow to a time domain voltage flow. The inverse Laplace transform is a complex integral known by a variety of names such as the brush integral, the Fourier-Melin integration, and the Mellin 'inverse formula. Another expression of the inverse Laplace change is a post conversion equation. In one embodiment, the time domain voltage flow is sent to a low pass amplifier 367, which is an increased voltage level with an appropriate signal period (duration) and an increased voltage level that is too short for use in subsequent circuit steps. Amplify the voltage flow while fractionating between short sections.

As an example, FIG. 8 shows time domain voltage flow output 400 from RF detector 366 to low pass amplifier 367. The time domain voltage flow 400 includes sections of increased voltage levels 410 and 420 that last for a variable amount of time. Longer increased voltage section 410 indicates that a significant amount of information is being sent by the local device, and a short increased voltage section 420 indicates "pings", which are very short indicating a small amount of information. Burst. Long sections of increased voltage are typical for certain local devices. In other words, the long increased voltage section 410 has a short or long low voltage section between the long increased voltage sections 410. This period, which varies depending on the type of local device used, is important in the level detector 370 discussion provided below.

In FIG. 9, low pass amplifier 367 generates a voltage flow, with long increased voltage section 410 (FIG. 8) resulting in higher voltage 412 and shorter increased voltage section 420 (FIG. 8 eventually generates a low voltage 422. This voltage flow 402 is then output from the RF detector circuit output 364 to the level detector 370. Those skilled in the art will readily understand what type of component should be used to generate the RF detection circuit 360 in accordance with the present invention and in accordance with a particular installation size request. RF detection circuit 360 The individual components present in one embodiment are shown in FIG. 6.

The level detector 370 is electrically connected downstream from the RF detection circuit 360, such that the output of the RF detection circuit is electrically connected to the level detector input 372 (FIG. 7). The level detector 370 generates an additional current based on the voltage flow provided by the RF detection circuit 360, wherein the voltage detector 370 includes at least one diode and at least one to store the provided current. Relatively large capacitor 376. The voltage flow 404 (FIG. 10) provided from the large capacitor 376 to the level detector output 374 allows any increased voltages 412 and 422 to exceed the period of voltage flow 402 from the RF detection circuit 360. Except that it lasts for a long period, it is associated with the voltage flow 402 provided by the RF detection circuit 360 at the level detector input 372. The magnitude of the period over which the increased voltage is maintained is closely related to the size of one or more capacitors, the magnitude of the resistor connected to it, and the current used by the subsequent device.

In FIG. 10, the level detector 370 has a long increased voltage period such that there is less voltage drop between the long increased voltage periods 414 resulting in a longer period of increased voltage 412. Generate a more consistent, voltage flow 404. This voltage flow 404 is then output from the level detector output 374 to the nonlinear amplifier 380.

A separate component present in one embodiment of the level detector 370 is provided in FIG. 7. Most components are well known to those skilled in the art, and the level detector 370 made in accordance with the present invention includes at least two 10 microfarad capacitors 376 sufficient to maintain a constant voltage for up to six seconds. This amount of time is sufficient to connect the message voltages 412 in the voltage flow 402 (FIG. 9) during the measurement by the microprocessor 310, which is described in more detail below. The time period depends on the harmony of the message sent and the speed of the processor 310.

In general, the period required to maintain a constant voltage during an embodiment of the invention amounts to ten times the long increased voltage 410 section period provided by the local device. Thus, such periods may vary depending on the local device used. The term "approximately" is also used in connection with a 10-fold multiplier, if the low voltage limit ("VIL") is reduced to allow greater voltage drop between long increased voltage sections 410. This is because 10 times or less may work well enough. More than ten times results in a period that is too long, in which case the voltage does not drop immediately past the VIL to properly stop the series (serial). These descriptions will be understood if the effects on the VIL and series are described in detail below. Those skilled in the art will readily appreciate that, according to the present invention, the amount of capacity suitable for a particular duration can be achieved by one large capacitor or many small capacitors.

In FIG. 3, a nonlinear amplifier 380 is electrically connected downstream from the level detector 370, such that the level detector output 374 is electrically connected to a nonlinear amplifier input 382 (FIG. 11). The nonlinear amplifier 380 compresses the voltage stream 404 provided by the level detector 370 to provide additional resolution for low voltages. In particular, the nonlinear amplifier 380 provides additional details at low voltages without the need to provide unnecessarily additional resolution at high voltages. This is because the microprocessor 310 receives the voltage flow from the nonlinear amplifier 380 at the nonlinear amplifier output 384 (FIG. 11) and converts it into a digital value in the range of 0-255, which is why Important in the examples. Additional resolution applied to the full voltage flow from the level detector 370 requires more than 255 digital values, and the voltage flow linear resolution from the level detector 370 eventually results in poor quality measurements of the upstream bandwidth. Individual components present in one embodiment of the nonlinear amplifier 380 are provided in FIG. 11. When there is an additional resolution in the microprocessor 310, the nonlinear amplifier 380 is not needed.

The nonlinear amplifier 380 is shown in FIG. 11 as including a resistor 386 located near the nonlinear amplifier input 382. This resistor 386 allows the voltage flow 404 from the level detector 370 to flow out without maintaining a certain voltage indefinitely. Thus, such a resistor 386 may be considered part of the level detector 370 or the nonlinear amplifier 380.

An example of changing the output voltage flow 440 nonlinearly and the input voltage flow 430 linearly is shown in FIG. 12. As shown in the figure, at a relatively low input voltage level, the output voltage flow 440 changes even more with respect to the change in the input voltage flow 430. However, at relatively high voltage levels, output voltage flow 440 changes smaller with respect to input voltage flow 430 variation.

FIG. 13 illustrates an example output voltage flow 405 generated in response to the voltage flow 404 provided in FIG. 10. As shown, the effect of the nonlinear amplifier 380 is to emphasize the details present at the low voltage and to ignore the high voltage. As discussed above, this effect of the nonlinear amplifier 380 is to help provide additional resolution for this low voltage for measurement purposes.

Again in FIG. 3, the microprocessor 310 is electrically connected downstream from the nonlinear amplifier 380 to allow the microprocessor 310 to be connected to the nonlinear amplifier output 384. The microprocessor 310 measures the individual voltages from the nonlinear amplifier 300 and can convert these voltages to 0-255 digital scales. 0-255 digital values were chosen in the present invention because of the capabilities of the microprocessor 310. Many other digital values, including actual voltage measurements, may only work depending on the capabilities of the microprocessor 310. Because of possible differences in measured values, the term "level value" will be used to describe the value assigned to a particular voltage input to the microprocessor 310 for further processing. As described above, the nonlinear amplifier 380 would not be necessary if the microprocessor 310 used included greater resolution capability than in this embodiment.

The operation and control for the upstream section 105 will be described in detail below with respect to the flowchart shown in FIG. 14. As described above, knowing that local devices automatically increase their output levels to offset any added attenuation effects, the upstream section 105 will intentionally attenuate the upstream bandwidth. Thus, for each amount of added attenuation, the signal-to-noise ratio of the upstream bandwidth increases because the noise is attenuated and because the local device increases the output of the desired frequency. The limit of this increase in signal to noise ratio is the amount of increase in the desired upstream bandwidth that can be added by the local device. Thus, the level in the upstream bandwidth will be investigated and monitored so that the amount of added attenuation will not continue to exceed the amount of additional output possible by the local apparatus.

과 버퍼 1을 사용한다.In FIG. 14, the microprocessor 310 operates through a series of processing steps 600 to determine the desired upstream bandwidth level value generated by the local device. As part of this decision, the microprocessor may

And buffer 1.

은 본 발명의 실시예에서 8 개의 입력 위치(

-7)를 갖는다. 상기 처리(600)에서, 버퍼

입력 위치들은 두 분리된 방식으로 나타내 진다. 먼저, 버퍼

입력 위치들은 특히 버퍼(

,

), 버퍼(

, 1), 버퍼(

, 2), 버퍼(

, 3), 버퍼(

, 4), 버퍼(

, 5), 버퍼(

, 6), 버퍼(

, 7)이다. 두 번째로, 버퍼

입력 위치는 버퍼(

, X)이며, X는 가변적이고 처리(600)의 일부로서 증가되고 리세트된다. 상기 버퍼

입력 위치의 평균은 본 명세서에서 현재 평균 값("CAV")이다.buffer

In the embodiment of the present invention, eight input positions (

-7). In the process 600, a buffer

Input positions are represented in two separate ways. First, buffer

Input locations are especially buffer (

,

), buffer(

, 1), buffers (

, 2), buffers (

, 3), buffers (

, 4), buffers (

, 5), buffers (

, 6), buffers (

, 7). Secondly, the buffer

Input position is buffer (

, X), where X is variable and is incremented and reset as part of the process 600. The buffer

The average of the input locations is the current average value ("CAV") herein.

- 7)를 갖는다. 상기 처리(600)에서, 상기 버퍼 1 입력 위치들은 특히 버퍼(1,

), 버퍼(1, 1), 버퍼(1, 2), 버퍼(1, 3), 버퍼(1, 4), 버퍼(1, 5), 버퍼(1, 6), 버퍼(1, 7)이다. 또한, 상기 버퍼 1 입력 위치는 버퍼(

, Y)이고, 이때 Y는 가변적이며, 처리(600)의 일부로서 증가되고, 감소되며, 그리고 리세트된다.Buffer 1 has eight input positions (

-Has 7). In the process 600, the buffer 1 input positions are in particular buffer 1,

), Buffer (1, 1), buffer (1, 2), buffer (1, 3), buffer (1, 4), buffer (1, 5), buffer (1, 6), buffer (1, 7) to be. In addition, the buffer 1 input position is a buffer (

, Y), where Y is variable and increases, decreases, and resets as part of the process 600.

과 버퍼 1 각각은 8개 이상 또는 이하의 입력 위치를 포함할 수 있다. 8개의 입력 위치가 업스트림 대역폭의 레벨을 얻기 위한 의도된 목적을 위해 잘 작용할 수 있지만, 보다 많은 입력 위치가 더욱 적은 변동성을 갖는 유연한 레벨 값을 제공할 수 있다. 이 같은 추가의 입력 위치는 한 레벨 측정과 추가의 처리기 소비를 얻기 위해 추가 시간의 비용으로 가능하게 된다.buffer

Each of the and buffers 1 may include eight or more input positions. Eight input positions may work well for the intended purpose of obtaining the level of upstream bandwidth, but more input positions may provide a flexible level value with less variability. Such additional input positions are made possible at the expense of additional time to obtain one level measurement and additional processor consumption.

으로 세트되며, 버퍼 1 입력 위치 Y가

으로 세트된다.Upon powering the regulator 100, the microprocessor 310 performs an initial routine, which includes steps 602, 604, 606, and 608. According to step 602, the input position X of the buffer is

Buffer 1 input position Y

Is set.

In accordance with step 602, the microprocessor 310 starts a setback timer, which is set to run for 10 minutes in this embodiment. As is clear from the following description, this 10 minute timer is made to release the attenuation located in the upstream bandwidth when there is no activity from the detected local device for 10 minutes. The term "activity" refers to the presence of a CAV above the high voltage limit ("VIH"). Ten minutes can be short or long, depending on the user's experience in a particular CATV network. The 10 minute time is chosen in the embodiment of the present invention assuming that most people using the Internet, VOIP or STB / STU will perform at least one function for a 10 minute time. No performance for a time interval longer than 10 minutes assumes that no user is currently using the Internet, VOIP or STB / STU.

In accordance with step 602, the return attenuator 320 (FIG. 3) is set to attenuation of 4 dB. This magnitude of attenuation is the base attenuation provided by the practice of the present invention with respect to adjuster 100. This base attenuation amount can be increased or decreased depending on the particular CATV system experience. This base size of 4dB is chosen because it provides some beneficial noise reduction. The size is low enough that the local device does not interfere with such a device being tested when it is first turned on and operating normally.

입력 위치 X가 8인가를 확인하도록 한다. 단계(604)의 목적은 버퍼

이 채워져 있는 가를 결정하는 것이다. 8의 크기는 X가 시드 값(seed value)(하기에서 설명됨)이 마지막 버퍼 위치(즉, 버퍼(

, 7))에 위치한 후에 1씩 증가되기 때문에 사용된다. 따라서, 비록 위치 "8"이 없더라도, 8의 값은 본 결정과 관련된다. "7" 값은 "X" 값을 증가시키는 단계가 처리(600) 내 다른 위치에서 발생된다면 사용될 수 있다. 단계(604)에 대한 답이 "no"이라면, 마이크로프로세서(310)은 단계(606)으로 이동한다. 그렇지 않다면, 마이크로프로세서(310)는 단계(608)로 이동한다. According to step 604, the microprocessor 310 buffers

Make sure the input position X is 8. The purpose of step 604 is to buffer

Is to determine if it is filled. The size of 8 means that X is the seed value (described below) and the last buffer position (that is, the buffer (

, Since it is incremented by 1 after being placed in 7). Thus, even if there is no position "8", the value of 8 relates to this determination. A value of "7" may be used if increasing the value of "X" occurs at another location in the process 600. If the answer to step 604 is no, then the microprocessor 310 proceeds to step 606. Otherwise, microprocessor 310 proceeds to step 608.

, X) 내로 위치시키는 데, 그 첫번째 경우는 버퍼(

,

)이다. 상기 시드 값은 경험적으로 발견되어질 것을 예상되는 레벨 값에 상대적으로 인접한 유도 값이다. 다시 말해서, 본 발명의 실시예에서 상기 시드 값은 특정 CATV 시스템에서 관찰된 실제 값들을 기초로 하여 실험적으로 결정된다. 상기 시드 값은 상기 조정장치(100)가 안정화 처리(stabilization process)를 시작하도록 업스트림 대역폭의 초기 레벨 값에 상대적으로 인접할 필요가 있다. 시드 값으로 버퍼(

, X)를 채운 뒤에, 버퍼(

)이 채워졌는지를 조사하기 위해 마이크로프로세서(310)는 단계(604)로 되돌아 간다. 단계(604)와 단계(606) 사이에서의 이 같은 처리는 모든 버퍼

입력 위치를 시드 값으로 계속하여 채우도록 한다. 일단 채워지면, 상기 마이크로프로세서(310)는 단계(608)로 이동한다.In accordance with step 606, the microprocessor 310 stores the seed value in a buffer (

, X), in the first case a buffer (

,

)to be. The seed value is a derived value relative to the level value expected to be found empirically. In other words, in an embodiment of the invention the seed value is determined experimentally based on the actual values observed in a particular CATV system. The seed value needs to be relatively adjacent to the initial level value of the upstream bandwidth for the regulator 100 to begin the stabilization process. Buffer as seed value (

, X), then buffer (

Microprocessor 310 returns to step 604 to check if < RTI ID = 0.0 > This process between steps 604 and 606 causes all buffers to

Continue filling the input position with the seed value. Once filled, the microprocessor 310 moves to step 608.

의 CAV를 얻을 것이며, 첫번째 경우 버퍼(1,

)인, 버퍼(1, Y) 내에 그 같은 값을 위치시킨다. 상기 마이크로프로세서(310)는 버퍼

입력 위치 X를

으로 리세트시키며, 그러나 상기 버퍼

입력 위치에는 시드 값을 남긴다. 본 발명 처리는 버퍼

내의 값이 지워지거나 나중에 그 위에 기록될 것으로 된다면 정상적으로 작용할 것이다.In accordance with step 608, the microprocessor 310 may buffer

Will get the CAV, and in the first case the buffer (1,

Is placed in the buffer (1, Y). The microprocessor 310 is a buffer

Input position X

Reset to the buffer

Leave the seed value at the input position. Invention process buffer

If the value in is cleared or written later on, it will work normally.

)인, 버퍼 (1, Y) 내에 위치하는 CAV 값에 따라 계산된다. 이는 CAV에 따라 VIH와 VIL을 계산하는 것으로 표현될 수 있기도 한다. 여하튼, VIH와 VIL은 나중 단계에서 기대된 레벨 값 근처가 아닌 대부분의 레벨 값을 배제하기 위해 사용된 계산된 값이다. 이 같은 배제는 상기 기대된 값들 훨씬 아래인 잘못된 피크 값 측정을 피함으로써 본 발명의 조정장치(100)가 더욱 더 안정될 수 있도록 한다. VIH와 VIL 모두는 모든 새로운 CAV가 결정된 뒤에 결정되기 때문에, VIH와 VIL은 수신된 레벨 값에서의 큰 변화가 있는 경우 유동(float) 하도록 허용된다. 본 발명의 실시예의 경우에, VIH는 버퍼(1, Y)의 대략 94%이며, VIL은 버퍼(1, Y)의 대략 81%이다. 두 VIH와 VIL은 보다 많거나 적은 레벨 값이 어떠한 피크 값 결정에서도 포함될 수 있도록 하는 다른 비(ratio)가 될 수도 있다. 상기 피크 값 결정이 하기에서 더욱 설명되지만, VIH는 VIH 이하 레벨 값은 고려에서 제외되는 높은 초기 한계값을 정한다는 사실을 이해하여야 한다. 마찬가지로, VIL은 낮은 이차 한계값이며, 이때 레벨 값은 특정 시리즈(레벨 값이 VIH를 초과한 때 시작하는)의 한 레벨 값이 VIL 이하일 때까지 고려된다. 다시 말해서, 일련의 레벨 값들이 단일 피크 값에 대하여 시험될 것이며, 상기 시리즈는 한 레벨 값이 VIH를 초과하는 레벨 값으로 시작되고, VIL 이하로 떨어지는 레벨 값으로 종료된다. 대부분의 최근 CAV가 51의 시드 값이기 때문에, VIH는 48인 것으로 계산되며 VIL은 41인 것으로 계산된다. 이들 값들은 물론 실제 레벨 값이 얻어진 뒤에 상기 CAV가 변경될 때 변경된다. 이와 같은 단계가 종료된 뒤에, 상기 마이크로프로세서(310)가 단계(610)로 이동된다.Also in accordance with step 608, the VIH and the low voltage limit ("VIL") are now buffer 1,

Is calculated according to the CAV value located in the buffer (1, Y). This can also be expressed as calculating VIH and VIL according to CAV. In any case, VIH and VIL are calculated values used to exclude most level values that are not near the level values expected in later steps. This exclusion allows the adjuster 100 of the present invention to be more stable by avoiding false peak value measurements well below the expected values. Since both VIH and VIL are determined after every new CAV has been determined, VIH and VIL are allowed to float if there is a large change in the received level value. In the case of the embodiment of the present invention, VIH is approximately 94% of the buffers (1, Y) and VIL is approximately 81% of the buffers (1, Y). Both VIH and VIL may be different ratios, allowing more or less level values to be included in any peak value determination. Although the peak value determination is described further below, it should be understood that VIH sets a lower initial threshold value that is excluded from consideration. Similarly, VIL is a low secondary threshold, where the level value is considered until one level value of a particular series (starting when the level value exceeds VIH) is below VIL. In other words, a series of level values will be tested for a single peak value, where the series begins with a level value where one level value exceeds VIH and ends with a level value falling below VIL. Since most recent CAVs have a seed value of 51, VIH is calculated to be 48 and VIL is calculated to be 41. These values are of course changed when the CAV is changed after the actual level value is obtained. After this step ends, the microprocessor 310 is moved to step 610.

In accordance with step 610, the microprocessor 310 obtains the current level value ("CLV"). The CLV is the voltage value provided by the nonlinear amplifier 380 at the present time. Once the CLV is obtained, the microprocessor 310 proceeds to step 612.

In accordance with step 612, the microprocessor 310 determines whether the currently obtained CLV is greater than the VIH to begin considering the series of level values. As explained above, if a particular CLV is the first obtained value greater than VIH (after having fallen below VIL), it is the first in the series. Thus, if the CLV is less than or equal to VIH, the microprocessor 310 proceeds to step 614 to determine if the CLV is less than VIL, and if so, will stop the series. If the CLV is greater than VIH, the next step is step 618.

In accordance with step 614, the microprocessor 310 makes a determination as to whether the recently obtained CLV is below VIL. As explained above, values at all levels that fall below VIL are excluded from consideration. This process 600 moves to step 616 when the CLV is below VIL. Thus, if the CLV is greater than VIL, the next step returns to step 610 to get a new CLV to continue the series started by having the CLV greater than VIH. None of these comparisons for VIH and VIL can be the same or small / large instead of just small / large. Additional values, used or unused, cannot significantly change the result.

입력 위치 X를 증가시키는 충분한 시간 단계(616)를 통해 진행되면, 버퍼

이 평균될 준비가 되었음을 나타내면서 단계(622)가 만족될 것이다.Once the microprocessor 310 is buffered

Proceed through enough time step 616 to increase the input position X,

Step 622 will be satisfied indicating that this is ready to be averaged.

의 평균인 CAV를 계산하며 버퍼

입력 위치 X를

으로 세트한다. 다음에 상기 마이크로프로세서(310)가 단계(626)로 진행된다.In accordance with step 624, the microprocessor 310 buffers

Calculates the average CAV of

Input position X

Set to. The microprocessor 310 then proceeds to step 626.

In accordance with step 626, the microprocessor 310 determines whether the CAV is greater than buffer (1, Y) +6. To clarify this step, if the buffers 1, Y are 51, the microprocessor 310 determines if the CAV is greater than 51 + 6, or 57. The value "6" added to buffer 1, Y adds stability to the process 600 because the CAV is high enough to add additional attenuation at step 629. Thus, values greater than "6" are used to add even greater stability when there is a risk of reducing accuracy. Similarly, values less than "6" are used to add even greater accuracy when there is a risk of reducing stability. Microprocessor 310 moves to step 629 to add attenuation if step 626 responds positively. If not, microprocessor 310 proceeds to step 628.

In accordance with step 629, the microprocessor 310 adds an additional attenuation step that is 1 dB in the embodiment of the present invention. Microprocessor 310 also increments buffer 1 input position Y to position CAV into buffer 1. Later, the microprocessor 310 moves to step 631.

-7)은 버퍼 1이 채워진 것을 나타낼 것이다. 이와 같은 이유가 하기 설명에서 명백하게 설명된다. 만약 버퍼 1이 채워진다면, 다음 단계는 단계(634)이다. 그렇지 않다면, 다음은 단계(632)이다.In accordance with step 631, the microprocessor 310 determines whether the buffer 1 input position has been filled. Since buffer 1 only has eight input positions, a value of 8 (

-7) will indicate that buffer 1 is full. This reason is clearly explained in the following description. If buffer 1 is filled, the next step is step 634. Otherwise, next is step 632.

According to step 632, the CAV is in the next open buffer 1 input position. The process then proceeds to step 636.

) 내 모든 값(즉 단계 634 이전)들이 버퍼 1로부터 이동되도록 한다. 다음에 CAV가 버퍼(1, 7) 내에 위치한다. 더욱더 단계(634)에서, 상기 버퍼(1) 입력 위치 Y는 7로 세트된다. 단계(632)에서와 같이, 만약 단계(600)가 단계(636)로 진행된다.Once the buffer 1 was filled, the microprocessor 310 proceeded to step 634 instead of step 632. According to step 634, all current values in buffer 1 are moved to the down 1 position, so that buffer 1,

) Causes all values () before step 634) to be moved out of buffer 1. Next, the CAV is located in the buffers 1 and 7. In step 634, the buffer 1 input position Y is set to seven. As in step 632, step 600 proceeds to step 636.

According to 636, microprocessor 310 calculates new values for VIH and VIL from buffers 1 and Y, which are buffers 1 and 7 if step 364 was previously achieved. After step 636, process 600 returns to step 610 to obtain a new CLV, and the relevant portions of process 600 resume.

Returning to step 628, the microprocessor 310 determines whether the CAV is less than the value in the buffers (1, Y)-4. Using the value for buffer (1, Y) 51, the microprocessor 310 will determine if the CAV is 51-5, or 47 or less. In such an embodiment, the process 600 will move to step 630. If not, the process 600 will move to step 638, which will be discussed further below.

In step 630, the microprocessor 310 determines if the time elapsed timer has timed out. If the answer is no, microprocessor 310 proceeds to step 646 where the time-lapse timer is reset. Otherwise, microprocessor 310 proceeds to step 642.

In accordance with step 642, the microprocessor 310 allows the buffer 1 input position Y to determine whether it is greater than or equal to four. If so, the microprocessor 310 moves to step 644, where the amount of attenuation applied by the variable attenuator 320 is reduced to four and the buffer 1 input position Y is reduced to four. A value other than "4" can be used if many decay reductions are desirable in view of time. A value of 4 is an appropriate value between applying sufficient attenuation to facilitate further loading in the local device and reacting too quickly to non-use of the local device. Later, microprocessor 310 moves to step 646 where the over time timer is reset.

으로 세트될 것이다. 나중에, 마이크로프로세서(310)는 단계(646)로 이동하여, 여기서 시간 경과 타이머가 리세트된다.Returning to step 648 again, if Y is not greater than or equal to 5 in step 642, the amount of attenuation applied by variable attenuator 320 is reduced to the base size of 4 defined in step 602, and the buffer 1 output location. Y is

Will be set. Later, microprocessor 310 moves to step 646 where the time-lapse timer is reset.

이라면, 마이크로프로세서(310)는 단계(636)로 직접 이동하여 새로운 VIH와 VIL을 계산하도록 한다. 그렇지 않다면, 상기 가변 감쇠기(320)는 단계(640)에서 한 단계가 줄어들며, 본 발명의 실시예에서 이는 1dB이다. 단계(640)에서, 버퍼1 입력 위치 Y는 1씩 줄어든다. 나중에, 마이크로프로세서(310)는 단계(636)로 이동한다.Returning to step 638, the microprocessor 310 causes the buffer 1 input position Y to

If so, the microprocessor 310 moves directly to step 636 to calculate the new VIH and VIL. Otherwise, the variable attenuator 320 is reduced by one step in step 640, which is 1 dB in the embodiment of the present invention. In step 640, buffer 1 input position Y is decremented by one. Later, microprocessor 310 moves to step 636.

Step 636 is the last step in process 600 before processing 600 begins again in step 610 without an initialization process. Microprocessor 310 may continue through process 600 when processing time permits.

Returning now to FIG. 3, the amount of attenuation determined by process 600 is added and added and reduced using variable attenuator 320 controlled by microprocessor 310. In accordance with the present disclosure, those skilled in the art will appreciate that there may be a variety of other hardware that will provide variable attenuation. For example, the implementation of the adjusting device 100 may include a fixed attenuator and a variable amplifier, which amplifier is connected to and controlled by the microprocessor 310. Other embodiments may be used including both variable amplifiers and variable attenuators. Further, the variable signal level adjusting device may be an automatic gain control circuit (“AGC”), and may work well in the device of the present invention. In other words, the amount of signal level adjustment and the amount of additional signal level adjustment can be achieved through a wide range of amplification and / or attenuation devices.

In the above description, the term "variable signal level adjuster" as used herein refers to variable amplifiers, AGC circuits, other variable amplifier / attenuation circuits, and related optics that can be used to reduce signal strength in upstream bandwidth. It is to be understood to include the circuit.

In FIG. 15, an optional upstream section 105 is described. In an embodiment of the present invention, the variable signal level adjuster, which is the variable attenuator 320 and the fixed amplifier 330, is controlled by the microprocessor 310 based on an input from the level detector 375. The level detector 375 measures and maintains the concurrent peak signal strength of the upstream bandwidth through the coupler 340 and the high pass filter 355. The microprocessor 310 of the embodiment of the present invention includes a counting circuit, a threshold value comparison circuit, and a level comparison circuit. Although the microprocessor 310 is used in the embodiment of the present invention, it is possible to control the variable signal level adjusting device in the manner described below using conventional logic circuits or microprocessors.

In FIG. 16, the variable signal level adjuster is shown to include a variable amplifier 335, which is connected to and controlled by the microprocessor 310 and the fixed attenuation device 325. Other embodiments are possible that include both variable amplifier 335 and variable attenuator 320.

The term “simultaneously generated signal strength” refers to the current signal strength as opposed to the signal strength measured in the past time (ie, previous signal strength), such as before applying signal level adjustment or applying further signal level adjustment magnitudes. The reason is evident in the following description.

In operation, in the embodiment shown in FIGS. 16 and 17, the microprocessor 310 performs the signal level setting routine 1000 provided in FIG. 17 to provide an appropriately sized signal level to be applied to the upstream bandwidth through the variable signal level adjusting device. Determine the adjustment. The signal level setting routine 1000 continues to be executed according to the command at predetermined intervals or as a result of the information signal transmitted by the provider 20. Once started, the microprocessor 310 or logic circuit performs the signal level setting routine 1000 in accordance with the flow chart shown in FIG.

With respect to FIG. 17, upon the start 1010 of the signal level setting routine 1000, the counting circuitry in the microprocessor 310 is reset to zero, for example at step 1020. The microprocessor 310 then repeats steps 1030, 1040, 1050, 1060, 1070, 1080, until the counter reaches a predetermined number (eg, 25) or the answer to step 1090 is negative. 1090).

In particular, in step 1030 microprocessor 310 reads the co-occurrence signal strength from signal level detector 375, and the counter is incremented in a predetermined increment such as 1 in step 1040. The microprocessor 310 next determines whether the counter is greater than a predetermined number (eg 25). If so, then microprocessor 310 terminates the routine; otherwise, microprocessor 310 proceeds to step 1060. In step 1060, the microprocessor 310 compares the co-occurring signal strength with a predetermined threshold. If the co-occurrence signal strength is greater than a predetermined limit value, the microprocessor 310 compares the co-occurrence signal strength with a predetermined limit value. If the simultaneous signal strength is greater than the predetermined threshold, the microprocessor 310 instructs the variable signal conditioner to further adjust the signal level (e.g. 1 dB), and if the concurrent signal strength is less than the predetermined threshold. Microprocessor 310 returns to step 1030.

After adding the additional signal level adjustment magnitude, the microprocessor 310 reads the new co-occurrence signal strength in step 1080, and the microprocessor 310 reads the previous read co-occurrence signal strength (in preparation for step 1090). That is, from step 1030) is stored as the previous signal strength. In step 1090, the microprocessor 310 compares the co-occurrence signal strength measured in step 1080 with the previous signal strength measured in step 1030. If the co-occurrence signal strength is equal to the previous signal strength, then microprocessor 310 returns to step 1030, but if the co-occurrence signal strength is less than the previous signal strength, microprocessor 310 proceeds to step 1100. ), Where the variable signal level is reduced to reduce the signal level adjustment by a predetermined amount (e.g., by an additional signal level scaling added in step 1070 or by an amount greater than the additional signal level adjustment added in step 1070). Instruct the adjuster. After step 1100, the microprocessor 310 stores the overall magnitude of the signal level adjustment at step 1110 and stops the routine at step 1120.

As mentioned above, an important feature of the current signal level setting routine is the comparison step performed at step 1090. The conventional cable modem 140 (FIG. 2) used in the CATV system can adjust its output level based on the information signal received from the provider in the downstream bandwidth. In particular, if the modem signal received by the provider 20 is weak, the provider 20 instructs the modem 140 to increase its transmission signal level. As this relates to the present invention, the modem 140 will continue to increase the signal level as a result of the increased amount of upstream bandwidth signal level adjustment until the modem 140 can no longer increase its transmit signal strength. . Thus, if the modem 140 can compensate for the additional signal level adjustment, after adding the additional signal level adjustment in step 1070, the concurrent signal strength measured in step 1070 should be equal to the previous signal strength. . However, if modem 140 is already generating the maximum signal strength, then the simultaneous signal strength will be below the previous signal when an additional amount of upstream bandwidth signal level adjustment is applied.

Because problems may occur in modem 140 when operating at full power (i.e., signal distortion is high when modem 140 is operating at or near maximum level, modem 140 is at or at maximum level). The lifetime of the modem 140 may be sacrificed when operating near it), so that in step 1100 the amount of signal level adjustment is reduced by a significant amount, so that when the maximum output strength of the modem 140 is confirmed, the modem It is possible to ensure the quality of the output signal generated by the 140 and the lifetime of the modem 140.

In a system with one or more devices sending data packets within the upstream bandwidth, the upstream section 105 can identify the maximum output strength of one device but not the other. In other words, the upstream section 105 identifies the first device that achieves the maximum output strength and does not identify the maximum output strength of any other device. If the upstream section 105 fails to identify the first observed maximum output strength, then such apparatus continues to operate at the maximum output strength until another decision cycle begins.

The determined number compared at 1050 is directly related to the magnitude of the signal level adjustment. For example, the variable signal level adjuster is a single stage attenuator, and for the embodiment shown in FIG. 16, it includes 25 stages of 1 dB, the best resolution (ie 1 dB) and the range of the specific stage attenuator (ie 25 dB). Can be set to 25 to allow broadband use. If faster overall operation is needed, the number of steps can be reduced and the resolution can be reduced (ie 5 steps of 5 dB). If a variable signal level adjuster having better resolution (i.e. 1 dB or less) or even wider bandwidth range (i.e. 25 dB or more) is used, the predetermined number can be reduced. The increment amount described herein with respect to the counter and the predetermined number is one (1), such that there are 25 repetitions (ie, 25 steps) when the predetermined number is 25. The increase may be any number (i.e., 1, 5, 10,-1,-10, etc.), and these numbers may be predetermined numbers determined based on the required resolution and required range of signal level adjustment and the required range, as described above. Depends on the total number of steps

The additional amount of attenuation added in step 1070 and the predetermined amount of attenuation reduced in step 1100 are all variable, depending at least in part on hardware design constraints, depending on the hardware experience experienced in certain CATV systems and certain CATV equipment. Conditions are adjusted by those skilled in the art. As described above, in one embodiment of the present invention, the variable signal level adjusting device includes a one-step attenuator having a resolution of 1 dB and a range of 25 dB. Thus, the additional amount of attenuation added in step 1070 using the hardware of an embodiment of the present invention may be 1 dB or a multiple of 1 dB. Similarly, the predetermined amount of attenuation reduced in step 1100 may be a multiple of 1 dB or 1 dB.

The predetermined threshold value compared in step 1060 is a signal level sufficient to distinguish the presence of upstream data packets in the upstream bandwidth from the interfering signals. This value varies with the cable modem 140, STB, STU, etc., output power in the system, and the average observed level of interfering signals. For example, the goal is to determine if there is an apparatus for sending upstream data packets over the upstream bandwidth. If the predetermined limit is too low, the interfering signals appear to be upstream data packets, and if the predetermined limit is set too high, the upstream data packets will appear to be interfering signals.

(iii) downstream section

3 and 18, the adjusting device 100 made in accordance with the present invention further comprises a downstream section 108 connected in the forward path 244.

In general, downstream section 108 uses microprocessor 310 to find and view channel level data using two different modes of operation, mode 0 and mode 1. In operational mode 0, the hippo 301 uses only a single high frequency channel and a single low frequency channel to allow relatively coarse / large correction in levels and slopes. In operation mode 1, microprocessor 310 uses two or more high frequency channel averages and two or more low frequency channel averages to make relatively fine corrections in terms of levels and slopes. In each mode in the embodiment of the present invention, the high frequency channel level is used to determine the amplification, and the level of the low frequency channel is used to determine the slope. In the simplest way described below, the high frequency channel level is used to determine the amplification, and the low frequency channel level is used to determine the slope. The operation of the hardware, control and downstream section 108 is described in detail below.

In the present invention, the microprocessor 310 is a microprocessor 310 as used in the upstream section 105. However, if there are advantages in terms of cost, space, or complexity, it is preferable to use two or more separate microprocessors 310. If two separate microprocessors 310 are used, there may be one connection between the two to allow information to pass through. As described below, there is an advantageous reason for the downstream section 108 to provide information to the upstream section 105. For example, these reasons reduce the upstream bandwidth attenuation, thereby preventing information flow through the upstream bandwidth when the signal transmission line between the coordinator 100 and the supplier 20 is damaged. This is discussed in detail below.

Regarding the hardware first, in FIG. 18, a coupler 502 is configured to pass a portion of the downstream bandwidth (called “connected downstream bandwidth”) to the tuner 506 via the second path 504. 244). The coupler 502 is provided between the user side deplexer 260 and a functional component (e.g., amplifiers 508 and 520, variable attenuator 512 and slope adjuster 514, all described in detail below). Is connected in forward path 244. The functional component is used to adjust the downstream bandwidth by correcting the level and slope of the downstream bandwidth. This position of the coupler 502 allows the downstream bandwidth to be adjusted and then sampled and analyzed. The coupler 502 used in the embodiment of the present invention is a conventional directional coupler and allows enduring continuous characteristic impedance. Other devices, such as simple resistors and / or splitters, may be used with careful consideration of the impact of these alternatives on the device's characteristic impedance.

A fixed signal level adjuster 516 is located between the coupler 502 and the tuner 506. The fixed signal level adjuster 516 may be used to prevent the coupler 502 from drawing too much power from the downstream bandwidth. The fixed signal level adjuster 516 is also sized to provide the tuner 506 with a connected downstream bandwidth having appropriately sized power for the duner 506 and the device that follows. Thus, those skilled in the art will understand whether a fixed signal level adjuster 516 is required and what size of fixed signal level adjuster 516 is required for a particular coupler 502 and tuner 506 combination.

The tuner 506 is a conventional tuner device that can be tuned to a selected channel based on input from a microprocessor 310. In particular, the tuner 506 used in the embodiment of the present invention is provided with a target index number (index #) corresponding to the CATV channel, shown in Table 1 below. The purpose of displaying these index numbers is to show that the CATV channels were not used in the ordinary way. For example, the frequency is lower than the CATV channel 14 (index # 10). Accordingly, the microprocessor 310 of the present invention controls the tuner 506 based on the index number which increases in increasing order with the frequency indicated by the index number. The purpose of this index number is explained in more detail below. More powerful microprocessor 310 and / or more complex software control may use an alternative method of selecting a channel other than the channel index shown below.

index # Channel specifier Channel bandwidth Low end High end 0 2 54 60 One 3 60 66 2 4 66 72 3 5 76 82 4 6 82 88 5 A-5 (95) 90 96 6 A-4 (96) 96 102 7 A-3 (97) 102 108 8 A-2 (96) 108 114 9 A-1 (99) 114 120 10 A (14) 120 126 11 B (15) 126 132 12 C (16) 132 138 13 D (17) 138 144 14 E (18) 144 150 15 F (19) 150 156 16 G (20) 156 162 ~ ~ ~ ~ 94 C91 624 630 95 C92 630 636 96 C93 636 642 97 C94 642 648 98 C100 648 654 99 C101 654 660 100 C102 660 666 101 C103 666 672 102 C104 672 678 103 C105 678 684 104 C106 684 690 105 C107 690 696 106 C108 696 702 107 C109 702 708 108 C110 708 714 109 C111 714 720 ~ ~ ~ ~

The output voltage flow from tuner 506 is a typical tuner, where the voltage flow is in the frequency domain, the voltage flow is in the standard television channel format, and in this embodiment the 6 MHz spectrum corresponds to the NTSC standard analog television channel format.

The relative narrow band pass filter 518 is electrically connected to the output of the tuner 506. The narrow band pass filter 518 removes external frequencies above or below the desired frequency provided by tuner 506 (eg, vertical synchronization frequency). Optionally, band pass filter 518 may be replaced by a low pass filter because the vertical synchronization frequency is modulated low in the frequency range according to NTSC. Similarly, band pass filter 518 may be replaced with a high pass filter that removes external signals below other desirable frequencies provided by the tuner, such as the horizontal synchronization frequency. It should be understood that other frequencies may be selected depending on the analog modulation method (eg NTSC, PAL, SECAN, etc.). The resulting frequency domain voltage flow is then sent to the RF detector 520.

The RF detector 520 converts the frequency domain voltage flow sent from the band pass filter 518 into a time domain voltage flow. In particular, the RF detector 520 performs the effect of an inverse Laplace transform, which is a widely used integral transform and allows the transform from the frequency domain to the time domain. As described above, the inverse Laplace transform is a complex integral, which is known by several names including the Bromine beach integration, Fourier-Melin integration, and the Melin inverse equation. As also described above, an alternative equation for the inverse Laplace transform is provided in the post inversion equation. Thus, any other device capable of such conversion from the frequency domain to the time domain can be used in place of the RF detector 520. Later, the time domain voltage flow is sent to both synchronization detectors 522 (“synchronization detector 522”) and low frequency level detector 524.

Synchronization detector 522 is synchronized with the voltage flow having a relatively continuous repetition such as a continuous 30 Hz tone. If there is no such continuous tone, the synchronization detector 522 provides a random output voltage stream. The random or synchronous or voltage flow output is then sent to low pass filter 526.

The low pass filter 526 is provided to attenuate high frequencies, which may appear as a synchronous frequency to the peak detector 528. Such low pass filter 526 is configured to include a desired synchronous frequency and to allow frequencies of at least 30 Hz to exclude frequencies above the desired frequency. Such low pass filter 526 may also include an input blocking capacitor to exclude very low frequencies.

Peak detector 528 generates a relatively consistent voltage when a voltage flow comprising the coincident voltage is provided from synchronous detector 522 and low pass filter 526. When there is a voltage flow that includes a random, non-simultaneous voltage, the peak detector 528 cannot consistently generate a voltage flow that is a large voltage above ground voltage. Such peak detector 528 may also be an integrator that performs a similar function.

The resulting voltage flow from the peak detector 528 is input along a path 530 into the microprocessor 310 as a signal that distinguishes between the analog modulation channel and the digital modulation channel. In particular, the voltage flow from the peak detector 528 is tuned to the analog modulation channel when the tuner 506 is at a significant voltage that is consistently above the ground voltage. In contrast, the voltage flow from the peak detector 528 indicates that the tuner 506 is tuned to the digital modulation channel when the voltage flow is constantly close to ground voltage.

As described above, the voltage flow from the RF detector 520 is directed to the level detector 524 to maintain the voltage level from the RF detector 520 for a longer period of time. In other words, the voltage in the voltage flow is fixed (not falling) at a certain rate for a longer period of time in the original voltage flow sent into the level detector 524. The voltage flow from the RF detector 520 is then input into the DC shift amplifier 532. The level detector 524 is also known as a peak detector.

The DC shift amplifier 532 is used as a low pass amplifier to provide a voltage flow that is scaled by a known amount to provide a suitable signal voltage for the microprocessor 310. The amount of voltage shift (shift) and / or amplification is determined by the voltage source 534 connected to the DC shift amplifier 532 by an appropriate attenuator 536. Thus, the DC shift amplifier 532 is also known as a low pass amplifier. Part of the voltage flow from the DC shift amplifier 532 is sent back to the tuner 506 as a control action. In addition, a portion of the voltage flow from the DC shift amplifier 532 is sent to the high gain amplifier 538, and a portion of the voltage flow from the DC shift amplifier 532 is sent to the low gain amplifier 540.

Amplifier 538 is provided with a voltage flow from DC shift amplifier 532 to act as a voltage comparator. This arrangement provides a voltage flow from the path 542 to the microprocessor 310 to identify the transmitted channel occurrences present at the index number tuned by the tuner 506.

Low gain amplifier 540 is also provided with a voltage flow sent from DC shift amplifier 532. The voltage flow generated by the low gain amplifier 540 is moved in response to the voltage source 544. The voltage source is coupled to the low gain amplifier 540 through an adjustable attenuator 546. The resulting voltage flow from the low gain amplifier 540 is related to the tuned index number of the channel level. This circuit arrangement provides a voltage flow in the path 548 to the microprocessor 310 to identify the level of one transmitted channel present at the index number tuned by the tuner 506.

The remaining portion of the downstream section 108 described below, to help perform the actual downstream adjustment function in the direction of the microprocessor 310. The actual control sequence of these devices is described in detail below, and the functions of the hardware will be described in detail first.

An amplifier 508 is provided at or near the first location in the downstream section 508 with respect to the downstream bandwidth flow. The amplifier 508 performs at least two functions. The first is that the amplifier 508 adds an additional level to the downstream bandwidth to calculate the inherent attenuation within the deplexer 265, the switch 255, and the like. Secondly, the amplifier 508 may add all or part of the amplification needed to correct the level and slope of the downstream bandwidth as part of the output compensation circuitry. For example, in the illustrated embodiment, the amplifier 508 may be a fixed output design (ie, not controlled by the microprocessor 310), and the adjacent variable attenuator 512 may be connected to the microprocessor 310. Can be controlled. As will be appreciated by those skilled in the art, a gain of 10 dB can be realized including a fixed 24 dB amplifier and 14 dB attenuation. In this regard, it should be understood that the combination of amplifier 508 and variable attenuator 512 is only one way of constructing an output compensation circuit that can be used to change the amplification / level. There may be many other configurations that can produce variable amplification. For example, the same desired amplification may be possible using a variable amplifier without the following attenuation device. In addition, known adjustable gain control (“AGC”) circuitry may replace the amplifier 508 and variable attenuator 512.

Slope adjustment circuit 514 may be provided. The slope adjustment circuit 514 changes the slope of the downstream bandwidth in response to the voltage provided from the rectifier 550. The slope adjustment circuit 514 provides a non-linear attenuation amount that resembles the inherent attenuation curve generated by the downstream bandwidth pass through the traditional signal cable. In particular, the slope adjustment circuit 514 provides nonlinear attenuation, where the high frequency is less attenuated than the low frequency, and the nonlinear curve is similar to the attenuation curve generated from the signal cable. Thus, after passing the signal cable length, the downstream bandwidth with the characteristic slope (this slope is a nonlinear curve with greater attenuation at high frequencies) is flat, or is made to have a somewhat upward slope to the slope adjustment circuit 514. .

Importantly, the slope adjustment circuit 514 does not provide amplification at the downstream bandwidth in order to flatten the levels at the downstream bandwidth. Instead, the slope adjustment circuit 514 attenuates frequencies with high levels. Thus, the presence of at least one amplifier 508, 510 and some form of control over some type of amplifier 508, 510 (e.g., variable attenuator 512) may be used to adjust downstream bandwidth with respect to slope and level. Will be needed.

The slope adjustment circuit 514 used in the embodiment shown in FIG. 18 changes the slope based on the voltage. Since the microprocessor 310 used in the embodiment does not output the variable voltage correctly, pulse width modulation (“PWM”) is used to control the slope adjustment 514. The signal output by the microprocessor 310 is converted into a corresponding variable voltage by the rectifier 550, which may be an integrator. One reference voltage is provided by the voltage source 552 to the slope adjustment circuit 514. The PWM signal can be replaced by digital control with analog output as will be appreciated by those skilled in the art.

Further describing the microprocessor 310, in particular how the microprocessor 310 can use the information provided to calibrate the level and slope of the downstream bandwidth, the first step is to calibrate the downstream section 108. It is. This calibration itself is not important, but the description of such calibration helps to introduce a number of terms useful in the following description. The calibration is accomplished by attaching the adjuster 100 to a matrix generator, which provides two or more known levels to the downstream apparatus, such as 0 dBmV and 20 dBmV at every index number. The calibration sequence proceeds as the tuner 506 increments in each of the index numbers (from the chart provided above) and obtains a calibration level for each of the index numbers. In an embodiment of the invention, this calibration level is stored as a digital value between 0 and 225.

Table 2 below is a chart of sample calibration levels, the values of which are selected for illustrative purposes only.

index # Channel specifier Scale level Low End 0dBmV High-end 20dBmV 0 2 155 210 One 3 165 225 2 4 155 218 3 5 160 223 4 6 155 214 5 A-5 (95) 148 205 6 A-4 (96) 168 224 7 A-3 (97) 168 231 8 A-2 (96) 159 217 9 A-1 (99) 163 224 10 A (14) 168 226 11 B (15) 150 213 12 C (16) 163 226 13 D (17) 167 224 14 E (18) 167 228 15 F (19) 161 224 16 G (20) 149 220 ~ ~ ~ ~ 94 C91 163 231 95 C92 166 220 96 C93 162 219 97 C94 148 208 98 C100 175 218 99 C101 162 212 100 C102 163 211 101 C103 172 235 102 C104 172 231 103 C105 158 202 104 C106 162 218 105 C107 151 209 106 C108 161 217 107 C109 163 213 108 C110 168 215 109 C111 159 216 ~ ~ ~ ~

Although two calibration values for each channel are shown in Table 2 above, it is possible to use only one calibration value for each with at least one assumption. For example, if the assumed increase is used for voltage change / when used, only one calibration value may be used.

Based on the calibration values obtained, the targets for the levels and slopes can be obtained through interpolation on the calibration values. For example, if the CATV provider determines that the levels should be 12 dBmV (or 14 dBmV) for the channels without any upward slope, the goal for each channel can be described in Table 3 below.

index # Channel designator Interpolation goal 12 dBmV 14 dBmV 0 2 188 194 One 3 201 207 2 4 193 199 3 5 198 204 4 6 190 196 5 A-5 (95) 182 188 6 A-4 (96) 202 207 7 A-3 (97) 206 212 8 A-2 (96) 194 200 9 A-1 (99) 200 206 10 A (14) 203 209 11 B (15) 188 194 12 C (16) 201 207 13 D (17) 201 207 14 E (18) 204 210 15 F (19) 199 205 16 G (20) 192 199 ~ ~ ~ ~ 94 C91 204 211 95 C92 198 204 96 C93 196 202 97 C94 184 190 98 C100 201 205 99 C101 192 197 100 C102 192 197 101 C103 210 216 102 C104 207 213 103 C105 184 189 104 C106 196 201 105 C107 186 192 106 C108 195 200 107 C109 193 198 108 C110 196 201 109 C111 193 199 ~ ~ ~ ~

Likewise, if the CATV provider decides to prefer 12 dBmV-14 dBmV up slope between 54 MHz and 1000 MHz for downstream bandwidth, the values described in Table 4 below can be interpolated as an example.

 index # Channel specifier Interpolation Target for 12dBmV-14dBmV
Up slope between 54 MHz and 1000 MHz dBmV value 0 2 12.0000 188 One 3 12.0127 201 2 4 12.0255 193 3 5 12.0382 198 4 6 12.0510 191 5 A-5 (95) 12.0637 182 6 A-4 (96) 12.0764 202 7 A-3 (97) 12.0892 206 8 A-2 (96) 12.1019 194 9 A-1 (99) 12.1146 200 10 A (14) 12.1274 203 11 B (15) 12.1401 188 12 C (16) 12.1529 201 13 D (17) 12.1656 202 14 E (18) 12.1783 204 15 F (19) 12.1911 199 16 G (20) 12.2038 192 ~ ~ ~ ~ 94 C91 13.2102 208 95 C92 13.2229 202 96 C93 13.2357 200 97 C94 13.2484 188 98 C100 13.2611 204 99 C101 13.2739 195 100 C102 13.2866 195 101 C103 13.2994 214 102 C104 13.3121 211 103 C105 13.3248 187 104 C106 13.3376 199 105 C107 13.3503 190 106 C108 13.3631 198 107 C109 13.3758 196 108 C110 13.3885 199 109 C111 13.4013 197 ~ ~ ~ ~

These interpolation targets are calculated by the microprocessor 310 at any time or provided to the microprocessor 310 in tabular form. Here it is explained to help clarify the use of target values and how these target values are obtained. Depending on the software strategy and the microprocessor 310, the use of goals in relation to these interpolated digital scale values may not be necessary. For example, the digital scale level values of a particular channel may be converted to a representative dBmV scale such that these targets remain on the dBmV scale. Also, for example, the digital scale level value of a particular channel is converted to a representative dBmV scale so that the target is a dBmV scale. In addition, many remaining components, such as slope adjuster 514, are calibrated to determine the amount of response of the device in relation to the amount of input from the microprocessor 310.

After calibration, when used at or near the user's area, the microprocessor 310 enters mode 0, which is an initial process of calibrating the levels of channels and slopes relatively quickly. Mode 0 will be described using the flowchart shown in FIG. 19 in conjunction with the relevant example in FIGS. 21-24.

In step 562, the hip 320 allows to identify the high frequency channel 810 (FIG. 21). Microprocessor 310 first identifies high frequency channel 810 at index # 103. If no channel index # is found, the microprocessor 310 starts scanning at index # 105 and down indexes until the high frequency channel 810 is identified as present. The specific index number used may be different in other embodiments. However, it is important to identify that a channel exists because one channel must be present to obtain the correct level values. In a typical CATV system, it has been found that there are channels in the index # 101 to 105 range. Thus, these index numbers must be changed to one location, where the channels are present in a particular CATV system, if necessary.

Microprocessor 310 obtains a level measurement for the identified channel. If the microprocessor (310) determines that the channel identified through the method described above is digital, the microprocessor (310) will add 10 dBmV at the level measured for that channel. Relevant digital values for an offset of 10 dBmV are described in Table 5 below.

index # Channel specifier Interpolated value for IdBmV target 1 dBmV 10 dBmV 0 2 2.75 27.5 One 3 3.00 30.0 2 4 3.15 31.5 3 5 3.15 31.5 4 6 2.95 29.5 5 A-5 (95) 2.85 28.5 6 A-4 (96) 2.80 28.0 7 A-3 (97) 3.15 31.5 8 A-2 (96) 2.90 29.0 9 A-1 (99) 3.05 30.5 10 A (14) 2.90 29.0 11 B (15) 3.15 31.5 12 C (16) 3.15 31.5 13 D (17) 2.85 28.5 14 E (18) 3.05 30.5 15 F (19) 3.15 31.5 16 G (20) 3.55 35.5 ~ ~ ~ ~ 94 C91 3.40 34.0 95 C92 2.70 27.0 96 C93 2.85 28.5 97 C94 3.00 30.0 98 C100 2.15 21.5 99 C101 2.50 25.0 100 C102 2.40 24.0 101 C103 3.15 31.5 102 C104 2.95 29.5 103 C105 2.20 22.0 104 C106 2.80 28.0 105 C107 2.90 29.0 106 C108 2.80 28.0 107 C109 2.50 25.0 108 C110 2.35 23.5 109 C111 2.85 28.5 ~ ~ ~ ~

Once the offset is applied, the microprocessor 310 determines if adjustment is needed. In mode 0, a threshold is set to determine whether the level should be adjusted and how many levels to adjust. In one embodiment, these limits and adjustment amounts are selected from Table 6 provided below.

condition Limit value Level adjustment

0 ≤ distance from target (in BmV) <3 dBmV No change One 3 ≤ distance from target (indBmV) <12 dBmV 2 dBmV 2 12 ≤ distance from target (indBmV) <40 dBmV 8 dBmV 3 40 ≤ distance from target (indBmV) 24 dBmV

According to step 564, if the distance from target indBmV drops to any of states 1 to 3, microprocessor 310 moves to step 566 and adjusts levels according to Table 6 above. If the distance from target indBmV falls to state 0, microprocessor 310 moves to step 568. As an example of level adjustment, the level curve 820 in FIG. 21 is amplified linearly so that a similar level curve 825 (FIG. 2) results. The difference between level curves 820 and 825 is that the level at 1000 MHz is located at the 12 dBmV target level in FIG. Although the levels have been shown to be increased above 20 dBmV in FIGS. 21 and 22, such a large amount of level adjustment cannot be achieved in one step according to Table 6. This large level increase is shown in FIGS. 21 and 22 for illustrative purposes only.

In accordance with step 568, the microprocessor 310 identifies the low frequency channel 805 (FIG. 21). For this purpose, microprocessor 310 first sends tuner 506 to index # 14. If no channel is identified at index # 14, the microprocessor 310 scans indexes 12-16 until one channel is identified. Similarly, it is important to identify at least one channel in the lower frequency portion of the downstream bandwidth. After one channel has been identified, the microprocessor 310 will get the level of that channel and if it is a digital channel will add 10 dBmV to that level.

According to step 570, the microprocessor 310 determines whether a slope change is required. Similarly, in mode 0 a threshold is set to determine how many slopes need to be adjusted and how many slopes need to be adjusted. In one embodiment, these limits and adjustment amounts can be selected from Table 7 provided below.

condition Limit value Slope adjustment

0 ≤ distance from target (in BmV) <3 dBmV No change One 3 ≤ distance from target (indBmV) <12 dBmV 2 dBmV 2 12 ≤ distance from target (indBmV) <40 dBmV 8 dBmV 3 40 ≤ distance from target (indBmV) 24 dBmV

According to step 570, if the distance from target indBmB comes to one of states 1-3, the microprocessor 310 moves to step 5 and adjusts the slope according to Table 7 above. If the distance from target indBmV drops to state 0, microprocessor 310 moves to step 520. As shown in FIGS. 22 and 23, the level curve 825 is attenuated in a non-linear fashion to form a level curve 830 which is shown to be 12 bBmV in the 54 MHz to 1000 MHz frequency range.

Similarly, the level curve 825 is attenuated in a nonlinear fashion to form the level curve 835 shown in FIG. 24 as having a 2 MHz up slope in the 54 MHz to 1000 MHz frequency range. Although the level curves 830 and 835 are shown as straight for illustrative purposes, these curves can have many variations from 54 MHz to 1000 MHz.

In accordance with step 570, the microprocessor 310 determines what adjustment should be made to either the level or the slope in the repetition of the process 560. If there is an adjustment in either the level or the slope, the microprocessor 310 returns to step 562 and repeats the process 560. If neither level nor slope is adjusted, the microprocessor 310 proceeds to mode one.

In FIG. 20, Mode 1 is similar to Mode 0 in that it looks for a high frequency channel 810 and a low frequency channel 805 to determine downstream bandwidth levels and slopes. The key difference is that Mode 1 uses more than two channels on average to find fine tuning for level and slope adjustments. This approach is not used in mode 0 because of the time required to gather the necessary information from a larger amount of channels. "Time required" is a direct result of the time needed for tuner 506 to change channel 506 and the time needed to measure. Mode 1 may be used instead of mode 0 if timing and rapid response are not of interest. These time related features are described in more detail in the following description.

According to step 582, the microprocessor 310 discovers at least two high frequency channels on average. In one embodiment of the downstream section 108, the microprocessor 310 starts at an index number 5 less than the start channel from mode 0 and ends at an index number 5 greater than the start channel from mode 0. In other words, the microprocessor 310 begins collecting channel information at index # 97 (ie 103-5) and ends collecting channel information at index # 109 (ie 103 + 5). The microprocessor 310 may also select a channel based on the index number representing the channel that is actually identified in mode 0, unless index # 103 includes a channel that can be identified. It should also be understood that fewer channels can be collected if the processing needs to be achieved quickly. Optionally, more channels can be collected if processing allows more time (more time than if less channels were collected). In other words, the time needed to select and measure channels is greater than the benefit of averaging more channels (e.g., mitigating the effects of randomly changing levels in adjacent channels), so that within a particular CATV system If adjacent channels are constant (ie do not vary arbitrarily), fewer channels may be collected. Similarly, because the additional accuracy obtained by averaging more channels than the additional time needed to select and measure the channels is more important, more and more channels can be collected if adjacent channels vary arbitrarily large in a particular CATV system. .

Based on the averages of the levels and targets for the identified channels in the scanned index number, the microprocessor 310 moves to step 584 to determine which level adjustment is necessary. If there are index numbers in the range that do not include identifiable channels, these channels will not be included in the average level or average target. Further, if the microprocessor 310 does not have enough channels to obtain a reasonable average, such as a five channel average in one embodiment, the downstream section 108 will not proceed to mode 1 and remains in mode 0. .

In accordance with step 584, the microprocessor 310 determines whether level adjustment is necessary. In mode 1, a threshold is set to determine whether the level should be adjusted and how much the level should be adjusted. In one embodiment, these limits and adjustment amounts are selected from Table 8 provided below.

condition Limit value Level adjustment 0 ≤ distance from target (indBmV) <3 dBmV No change One 3 ≤ distance from target (indBmV) <12 dBmV 1 dBmV 2 12 ≤ distance from target (indBmV) Return to mode 1

In accordance with step 584, if the distance from target (indBmV) corresponds to any of state 1, microprocessor 310 moves to step 588 and adjusts the level according to the table. If the distance from target (indBmV) corresponds to state 2, microprocessor 310 moves to step 586, where it returns to mode zero. In this case it is necessary to go back to mode 0 because the amount of adjustment needed is too long to resolve the rapid changes that occur somewhere between the supplier 20 and the downstream section 108.

Microprocessor 310 then moves to step 590 to find two or more low frequency channel averages. In one embodiment of the downstream section 108, the microprocessor 310 starts with an index number two less than the start channel from mode 0 and ends at an index number two greater than the start channel from mode 0. In other words, the microprocessor 310 will begin collecting channel information at index # 12 (ie 14-2) and will end collecting channel information at index # 16 (ie 14 + 2). The microprocessor 310 may also select a channel based on the index number that represents the channel that is actually identified in mode 0 if index # 14 does not include a channel that can be identified. The downstream section 108 collects only five low frequency channels, while there are 11 high frequency channels, since the low frequency channels are more consistent and the level is more constant. It is to be understood that more or less channels may be collected if the degree matters or if the channels in a particular CATV system are more or less constant.

Based on the average of the levels and targets for the identified channels in the scanned index number, the microprocessor 310 proceeds to step 592 to determine if slope adjustment is required. If there are index numbers in the range that do not include an identifiable channel, these channels will not be included in the average level or average target.

In accordance with step 592, the microprocessor 310 determines whether slope adjustment is required. In mode 1, a threshold is set to determine whether to adjust the slope and how many levels to adjust. In one embodiment, these limits and adjustments are determined from the values described in Table 9 below.

condition Limit value Slope adjustment

0 ≤ distance from target (indBmV) <3 dBmV No change One 3 ≤ distance from target (indBmV) <12 dBmV 1 dBmV 2 12 ≤ distance from target (indBmV) Return to mode 0

According to step 592, if the distance from the target in dBmV corresponds to either state 0 or 1, the microprocessor 310 moves to step 596 and adjusts the slope according to Table 9 above. If the distance from state 2 corresponds to state 2, microprocessor 310 moves to step 594 and returns to mode 0. In this case it is necessary to go back to mode 0 because the amount of adjustment needed is too long to account for the rapid change that occurred somewhere between the supplier 20 and the downstream section 108. Thus, this return to mode 0 is in response to rapid changes in levels, such as when the cable is damaged or the amplifier fails quickly.

There may be minor changes to the device without major changes in design and operation of the downstream section 108. Typically, the use of high and low frequency channels can be reversed. In particular, the downstream section will act so that the low frequency channel is used to set the level and the high frequency channel is used to set the slope.

In an optional embodiment, the microprocessor 310 directs the tuner 506 to scan the coupled downstream bandwidth, so that a low frequency, referred to herein as a low frequency channel 805 (FIG. 21) And a channel having a high frequency called a high frequency channel 810 (FIG. 22) herein. In an embodiment of the invention, the microprocessor 310 instructs the tuner 506 to scan toward a higher frequency starting at a relatively lower frequency in the downstream bandwidth until the low frequency channel 805 is found. Similarly, microprocessor 310 instructs tuner 506 to scan toward a lower frequency starting at a relatively high frequency in the downstream bandwidth until the high frequency channel 810 is found. Thus, the low frequency channel 805 may be one channel found near the lowest frequency in the concatenated downstream bandwidth, and the high frequency channel 810 is found near the highest frequency in the concatenated downstream bandwidth. It may be one channel. Although in the embodiment of the present invention, the low frequency channel 805 and the high frequency channel 810 are shown as being single frequency in FIG. 21, one channel is usually a range of frequencies.

In an embodiment of the invention, the low frequency channel 805 and the high frequency channel 810 need not be the lowest or highest frequency channel, respectively. However, to best evaluate the parasitic losses over the entire downstream bandwidth, it is desirable that the two channels are as far apart from each other as possible.

During the scanning process for identifying and identifying the low and high frequency channels 805 and 810 of the embodiment of the present invention, the microprocessor 310 may be configured as described above in connection with the implementation of the downstream section 10. Three kinds of information can be provided. First a signal is provided to microprocessor 310 via path 542 indicating that one channel has been identified. Second, a signal indicative of the level of the identified channel is provided to microprocessor 310 via path 548. Third, a signal indicative of the modulation of the identified channel is provided to microprocessor 310 via path 530.

As mentioned above, digital format channels have less signal strength than corresponding analog channels. In an embodiment of the invention, such a difference in signal strength is 6 dB. Thus, the microprocessor 310 of the embodiment of the present invention includes a level offset calculation that can account for a 6 dB difference when comparing the relative signal strengths of the low and high frequency channels 805 and 810. If this difference is not accounted for, any result comparisons for the two channels 805, 810 to determine the relative signal strengths will be wrong. For example, if the high frequency channel 810 is digital and the low frequency channel 805 is analog, then the additional, inherent 6 dB difference would incorrectly indicate that there are more parasitic losses than are actually present. Similarly, if the high frequency channel 810 is analog and the low frequency channel 805 is digital, any result comparison will incorrectly indicate that there is less parasitic loss than is actually present. Thus, it should be understood that the 6 dB offset is added to the signal strength of the digital format channel or the 6 dB offset is subtracted or has nothing to do with the signal strength of the analog format channel.

Also, if both low and high frequency channels 805 and 810 are digital, a 6 dB offset can be added to both signal strengths, and if both low and high frequency channels 805 and 810 are analog, then from both signal strengths, It should be understood that the 6 dB offset can be subtracted. Moreover, the offset magnitude is indicated by a standard that a particular supplier complies with, so the offset magnitude may be greater than 6 dB, such as 10 dB described above.

After the scanning process and the process of adding / removing the offset, the microprocessor 310 performs the low frequency channel level (including any offset), the low frequency channel frequency, the high frequency channel level (including any offset), and the high frequency. Has a band channel frequency. Known information (e.g., level and frequency) of the low and high frequency channels 805, 810 is now compared to the signal strength gain / loss curve (i.e. gain / loss curve) defined by the microprocessor 310 and The predetermined signal strength gain / loss curve corresponds to a known parasitic loss associated with the type of coaxial / optical cable used as shown in FIG. This step allows the known information to be interpolated over the entire downstream bandwidth. Using this interpolation curve, the microprocessor 310 determines how many signal level adjustments should be applied and how it should apply the level adjustments across the entire downstream bandwidth, so that the gain / loss curve of the hook over the entire bandwidth (I.e., the slope) is nearly linear and preferably increases slightly toward higher frequencies in anticipation of parasitic losses that will occur downstream of adjuster 100. For example, the amount of level increase is determined by the high frequency channel level, including interpolation for the highest frequency, and the amount of level decrease is determined by the low frequency channel level, including interpolation for the lowest frequency.

It is to be understood that parasitic losses affect the higher frequencies more than the lower frequencies. Thus, if a known signal with a -10 dB signal strength is transmitted at various frequencies in the entire downstream bandwidth and in the coaxial / optical cable length, the resulting slope is made. Because the end goal is to have a straight line near the original signal strength, or to have a slope with increasing slope vs. frequency, the microprocessor 310 directly controls the variable slope adjustment circuit so that the lower frequencies have higher amplitude than the higher frequencies. Adjust the downstream signal transmission in a curved manner so that it is small.

For example, as shown in FIG. 21, using known frequencies and signal strengths for each of the low frequency channel 805 and the high frequency channel 810, a gain curve 820 can be made at the entire downstream bandwidth. Which is shown to be between 50 MHz and 1000 MHz. The microprocessor 310 then determines the total amount of level adjustment to be added by the amplifier 508 and the amplifier 510 in combination with the variable attenuator 512 that will replace the loss at least at the highest frequency.

In an embodiment of the present invention, the level adjustment amount is at least +24 dB, resulting in making the gain curve 825 shown in FIG. Based on the interpolated gain curves shown in FIG. 21, the microprocessor 310 instructs the slope adjuster 514 to apply a similar but opposite curve correction amount to eventually be relatively flat as shown in FIG. 23. Create a gain curve (ie, slope) 830. In order to increase the amount of level adjustment applied and increase the slope adjustment curvature, it is desirable to create a gain curve (ie, slope) 835 with a slope that increases toward higher frequencies, as shown in FIG.

(iv) interaction between the upstream section 105 and the downstream section 108

As described above, downstream section 108 transitions from mode 1 to mode 0 when there is a rapid change in level, such as when a cable is damaged or when an amplifier outside adjuster 100 fails. The reason for changing from mode 1 to mode 0 is that the downstream section 108 rapidly increases the amount of amplification used to achieve the desired level amount and / or quickly increases the amount of slope compensation used to achieve the desired slope. This is because by increasing the downstream section 108 can respond to such damage.

The term "quickly" as used herein has a relative meaning. The actual levels and slopes of a particular CATV system change from day to day due to environmental changes such as temperature changes, sunlight, and humidity. If there is any change other than these normal fluctuations, the change is indicative of damage occurring or occurring between the adjusting device 100 and the supplier 20. The normal variation is usually specified for a given CATV system and / or geometric position, and the magnitude of these normal variation is known to the technicians working in the particular CATV system. Thus, the term " quickly increasing " indicates that there is a degree of amplification and slope beyond that associated with normal fluctuations for a particular CATV system.

The term "amplification degree" refers to the degree per unit time that amplification is applied to the downstream bandwidth. Similarly, the term “slope degree” refers to the degree per unit time that slope correction is applied to the downstream bandwidth.

While downstream section 108 may compensate for damage occurring or occurring within the CATV system between coordinator 100 and supplier 20, upstream section 105 may have a desired upstream bandwidth by local devices. It is not known what damage has occurred by measuring whether it has occurred. In fact, the upstream section 105 creates a problem when such damage occurs, since the upstream section 105 effectively eliminates the additional capacity of the local device to increase its output level. Any loss due to damage will be added to the overall attenuation caused by the upstream section 105 and will no longer allow the local device to communicate with the supplier 20.

In order for the upstream section 105 to account for any damage occurring or occurring in the CATV system between the adjuster 100 and the supplier 20, the downstream section when a transition from mode 1 to mode 0 occurs. 108 may provide an indication to the microprocessor 310 that the amplification and / or slope correction values are changing rapidly. If the same microprocessor 310 is being used for the operation and control of both sections 105, 108, then the microprocessor 310 is configured to allow the microprocessor 310 to adjust the downstream section 105 to control the upstream section 105. There is no need to receive another indication from section 108.

In FIG. 25, the process 700 is described with respect to the operation and control of the upstream section 105 in response to the abnormal variation observed from the upstream section 108. The process 700 is presented and described only for amplification (i.e., amplification value and degree of amplification), for clarity of the present description, and the same process 700 is slope (i.e., slope value and slope degree). Or based on both amplification and slope.

In step 705, the microprocessor 310 retains the downstream amplification value in the first buffer. The term "retain" is broadly interpreted to allow the possibility that the downstream section 108 includes its own microprocessor, thus sending the downstream amplification value to the microprocessor. The term is also broadly interpreted to allow the downstream section 108 to exploit the possibility of using the microprocessor 310 with the upstream section 105.

In step 705, the microprocessor 310 restarts the degree counter. The degree counter herein allows to provide a timing function to measure the elapsed time between retained downstream amplification values. Thus, there are a variety of other known ways for the microprocessor to measure elapsed time. For example, microprocessor 310 may include a clock, such that step 705 includes the time at which the downstream amplification value was held. Similarly, retaining downstream amplification values occurs at specific times so that no accuracy counter or other clock is needed.

In step 710, a check is made to see if an amplification value exists in the second buffer. This step allows for a start condition where no amplification values are yet stored in the second buffer. As in the initial execution case of process 700, if there is no amplification value in the second buffer, then microprocessor 310 will store the amplification value in the first buffer into the second buffer and return to step 705. If there is already an amplification value in the second buffer, the microprocessor 310 will proceed to step 720.

In step 722, the microprocessor 310 will calculate the amplification degree change using the amplification value in the first buffer, the amplification value in the second buffer, and the Rate Counter. In particular, the amplification value in the second buffer is subtracted from the amplification value in the second buffer, and the result is divided by the degree counter. The calculated degree of amplification then proceeds to step 725.

In step 725, the microprocessor 310 determines whether the amplification degree is greater than the threshold value. The purpose of this step is to determine whether the currently observed degree of amplification is outside the typical variable marginal region of a particular CATV system. The threshold degree can also be set very high, such as at about 3 db per minute.

The reason for this is that damage accidents such as tree branches falling onto power lines or cars hit power poles occur very quickly. In addition, these rapid changes can adversely affect the ability of the upstream section 105 to account for such damage. If the amplification degree is greater than the threshold value, the upstream attenuation level in the upstream section 105 is reset to remove the attenuation added in step 730. Otherwise, if the amount of amplification is below the threshold, there is no change in the upstream attenuation level. In either case, after the result, the microprocessor 310 proceeds to step 735.

In step 735, the microprocessor 310 replaces the value in the second buffer with the value in the first buffer and returns to step 705.

In optional embodiments, the downstream section 108 may provide the amount of ongoing amplification and / or slope information directly from the downstream section. In such an embodiment, the microprocessor 310 only needs to monitor the amount of amplification and / or slope and reset the upstream attenuation level when at least one of the degrees exceeds the threshold.

As described above, in one embodiment, the downstream section 108 may include two mode (ie, mode 0 and mode 1) adjustment processing to provide amplification and / or slope adjustment. In the first mode, there is adjustment in larger increments, and in the second mode there is adjustment in smaller increments.

In such a scenario, the first mode can be used whenever the upstream section 108 determines that a large adjustment (greater / faster than the adjustment in the second phase) is needed. Since switching from the second mode to the first mode indicates that larger adjustments are needed for amplification and / or slope adjustments, this transition causes the upstream section 105 to reset the upstream attenuation level and eliminate any additional attenuation. It can be used as an indicator.

(v) Frequency band selector

In FIG. 26, the adjusting device 100 may include a circuit component for generating a frequency band selecting device. The frequency band selector may be configured to automatically switch between a configuration corresponding to data ("DOCSIS") through a previous cable service interface specification and a recent generation specification such as DOCSIS 3.0. This feature benefits itself in the adjuster 100, but allows other devices such as the upstream section 105 and / or downstream section 108 to be useful even after a change between specifications. In particular, a necessary change in upstream / downstream bandwidth may render sections 105, 108 inoperable, because each of these sections 105, 108 requires precise separation of the signal between upstream bandwidth and downstream bandwidth. Make. Although the DOCSIS specification is mentioned above and below, upstream / downstream bandwidth configurations may be maintained and changed according to any protocol specification.

The adjustment device 100 of the embodiment shown in FIG. 26 has been simplified to illustrate only the frequency and the selection device, and each of the optional upstream section 105 and downstream section 108 is represented by a box shown in dashed lines. The adjusting device 100 of the embodiment of the present invention includes a plurality of switches 902, 904, 916, 918, 922, and 924 that define the first signal path set 910 and the second signal path set 920. Each set of signal paths includes two discrete signal paths, a forward path 930 and a return path 940. The first signal path set 910 is formed using a pair of first frequency band splitters 906, 908, and the second signal path set 920 uses a pair of second frequency band splitters 912, 914. Is formed. The cutoff frequency defined by the first pair of frequency band splitters 906 and 908 corresponds to the DOCSIS specification with a narrow / small upstream bandwidth, and the cutoff frequency defined by the second pair of frequency band splitters 912 and 914. Corresponds to a later DOCSIS specification, which later includes wider and larger upstream bandwidth than the previous DOCSIS standard. The cutoff frequency can be changed to accommodate an even newer DOCSIS standard or other standard by merely replacing the first pair of frequency band splitters 906, 908 and / or the second phase of frequency band splitters 912, 914. Should be understood. Any high quality, commercially available switch and frequency band dividing device may work well at a particular location within the regulator 100.

Each of the switches 902, 904, 916, 918, 922, 924 can be adjusted directly or indirectly by the microprocessor 310. Microprocessor 310 preferably switches to first signal path set 910 or second signal path set 920 to switch 902, 904, 916, 918, 922, 924 based on the information transmission signal sent by supplier 20. Decide whether to activate). The signal coupler 850 is well known to the receiver 845 to receive other information transmissions that may be understood by the microprocessor 310 to indicate an information transmission signal such as a sound, an encrypted operation signal, or a switch position. To help. For example, the presence of the information signal may be used to indicate that the microprocessor 310 should select the second signal path set 920, but any information signal may be used by the microprocessor 310 for the first signal path set 910. It does not indicate that should be selected. For example, the presence of 900 MHz continuous tones can be identified by passing a signal through a band pass filter 840 as long as it has a constant tone to eliminate unnecessary signals and comparators 855. The comparator only provides such a sound to the microprocessor 310 when it is / is stronger than a predetermined threshold determined by one voltage source 865 and resistive voltage divider 860. The frequency can be selected by the microprocessor 310 and tuned by the phase-locked loop control system 880 and the amplifier 870 in a manner well known in the art. High quality, commercially available signal couplers, and receivers will work well with the adjuster 100 within certain locations.

While the present invention has been shown and described with reference to certain embodiments, those skilled in the art will recognize that various changes to the details may be practiced without departing from the spirit and scope of the invention as defined by the claims supported by the detailed description. I will understand. In addition, although embodiments of the present invention have been described with a certain number of components, it will be understood that they may be used using components below or above such a number of components.

Next, various embodiments of the present invention will be described using the claims description format.

A1. An upstream bandwidth adjuster that can be inserted into a signal transmission line of a CATV system near or adjacent to a user's area.

A variable signal level adjuster configured to generate a signal level adjust amount for the upstream bandwidth;

A signal measuring circuit configured to measure a second signal strength after applying the first signal strength value of the upstream bandwidth and the additional signal level adjustment amount before applying the additional signal level adjustment increment; And

circuitry configured to (i) compare the first signal strength with the second signal strength and (ii) remove at least a portion of the additional signal level adjustment increment when the first signal strength is greater than the second signal strength. Upstream Bandwidth Regulator.

A2. In A1, wherein the first frequency band dividing device is located between the variable signal level adjusting device and the user side; And

And a second frequency band dividing device is located between the variable signal level adjusting device and the supplier side.

A3. The signal signal measuring circuit of claim 1, wherein the signal signal measuring circuit comprises a signal level detector configured to output a signal representative of one level of the upstream bandwidth after applying the signal level adjustment amount and applying the additional signal level adjustment increment amount. Adjusting device.

A4. The apparatus of claim A3, wherein the signal level detector is configured to maintain a signal representative of the upstream bandwidth level for the time required for the circuit to read the signal strength.

A5. The adjusting device according to claim 1, wherein the circuit can hold at least one of the first and second signal strengths until later in use.

A6. The adjusting device according to claim A1, wherein the circuit is configured to repeatedly determine whether additional signal level adjustment increments should be applied.

A7. The adjusting device according to A6, wherein when the first signal strength is greater than the second signal strength, the circuit stops repetitive determination and removes a part of the additional signal level adjustment increment.

A8. The adjusting device according to A6, characterized in that it is configured not to apply an additional signal level adjustment increment amount in one determination period when the second signal strength is below a predetermined threshold value.

A9. The regulating device of A1, wherein the circuit is a microprocessor.

A10. The adjusting device according to A1, wherein the circuit is an analog circuit.

A11. The adjusting device according to claim 1, wherein the circuit is further configured to compare at least one of the first signal strength and the second signal strength with a predetermined threshold value.

A12. As a way to adjust the upstream bandwidth transmitted over a CATV system transmission line using a device located in your area:

(a) providing a device having a user side and a provider side;

(b) providing a variable signal level adjusting device between the user side and the supplier side;

(c) measuring a first signal strength value of the upstream bandwidth at an upstream location from the variable signal level adjuster;

(d) apply additional signal level adjustment increments to the upstream bandwidth;

(e) measuring a second signal strength value;

(f) compare the first signal strength value with the second signal strength value;

(g) repeating steps (c) to (f) for a predetermined number of cycles,

Wherein a portion of the additional level adjustment increment is removed when the second signal strength value is less than the first signal strength value.

A13. The method for adjusting the upstream bandwidth of A12, characterized in that the predetermined number of periods is (2) or more.

A14. The method of claim 14, further comprising comparing at least one of the first signal strength and the second signal strength with a predetermined threshold.

A15. As a way to adjust the upstream bandwidth transmitted over a CATV system transmission line using a device located in your area:

(a) providing a device having a user side and a provider side;

(b) providing a variable signal level adjusting device between the user side and the supplier side;

(c) measuring a first signal strength value of the upstream bandwidth at an upstream location from the variable signal level adjuster;

(d) apply additional signal level adjustment increments to the upstream bandwidth;

(e) measure a second signal strength value after the signal level adjustment additional amount has been applied;

(f) compare the first signal strength value with the second signal strength value;

(g) proceeding to step (i) when the second signal strength value is less than the first signal strength value;

(h) repeating steps (c) to (g) for a predetermined number of periods, and proceeding to step (j) when the predetermined number of periods are finished;

(i) reduce the additional signal level adjustment increment by a predetermined amount and proceed to step (j); And

(j) providing continued signal level adjustment for the upstream bandwidth.

A16. The method for adjusting upstream bandwidth of A15, characterized in that the predetermined number of periods is (2) or more.

A17. The method of A15, further comprising comparing one of the first signal strength and the second signal strength with a predetermined threshold value.

B1. As a downstream bandwidth output level and / or output level slope compensation device that can be inserted into a CATV system transmission line at, near, or in proximity to a user's area:

A tuner configured to scan the downstream bandwidth to identify the low frequency channel and the high frequency channel;

A channel analyzer configured to determine formats of each of the low frequency channel and the high frequency channel;

A signal measuring device configured to measure a low frequency channel level of the low frequency channel and a high frequency channel level of the high frequency channel;

(i) add an offset value to the low frequency channel level when the low frequency channel is in digital format, (ii) subtract an offset value from the low frequency channel level when the low frequency channel is in analog format, and (iii) Add an offset value to the high frequency channel level when in this digital format, and (iv) subtract one gain offset value from the high frequency channel level when the high frequency channel is in analog format An offset circuit configured to perform;

A microprocessor configured to compare the low frequency channel level and the high frequency channel level with a predetermined signal strength loss curve including offset values;

Variable output level compensation device additional function; And

A downstream bandwidth output level and / or output level slope compensation device comprising a variable slope adjustment circuit addition.

B2. Wherein the variable output level compensation device and the variable slope adjustment circuit are configured such that the gain associated with the high frequency channel is greater than the gain associated with the low frequency channel.

B3. 2. The apparatus of B1, wherein the predetermined signal strength loss curve is a standard loss curve representative of a transmission line used at or near the CATV subscriber region.

B4. The apparatus of B1, wherein the tuner is configured to scan from the maximum frequency to the low frequency to find the high frequency channel and is configured to scan from the minimum frequency to the high frequency to find the low frequency channel.

B5. The apparatus of B1, characterized in that the signal level adjustment amount provided by the variable output level compensation device is determined based on the high frequency channel level.

B6. 2. The apparatus of B1, wherein the amount of slope adjustment provided by the variable slope adjustment circuit is determined based on the low frequency channel level.

B7. The apparatus of B1, wherein the signal measuring circuit is configured to measure the high frequency channel level and the low frequency channel level downstream from the variable output level compensation circuit.

B8. A method for adjusting downstream bandwidth in a CATV service user area,

Receive downstream bandwidth from a CATV provider;

Scan the downstream bandwidth to obtain a low frequency channel and a high frequency channel;

Measure a low frequency channel level of the low frequency channel and a high frequency channel level of the high frequency channel;

 Determine a low frequency channel description format;

Determine a high frequency channel description format;

Offset one of the low frequency channel level and the high frequency channel level with a predetermined offset when one channel among the low frequency channel and the high frequency channel is an analog format and one channel among the low frequency channel and the high frequency channel is a digital format ;

Compare the low frequency channel level and the high frequency channel level including the offset value with a predetermined signal strength loss curve;

Provide an output level compensation amount at downstream bandwidth; And

A method for adjusting downstream bandwidth comprising providing a slope adjustment with downstream bandwidth.

B9. The method of B8, wherein the slope adjustment amount is determined such that the gain associated with the high frequency channel is greater than the gain associated with the low frequency channel.

B10. The method of claim B8, wherein the predetermined signal strength loss curve is a standard loss curve representative of the signal transmission line used in, near, or adjacent to the subscriber area.

B11. The method of claim B8, wherein scanning is performed to find the high frequency channel starting from the maximum frequency and extending toward the low frequency.

B12. The method of claim 8, wherein the scanning is performed starting from the minimum frequency and extending toward the high frequency to find the low frequency channel.

B13. The method of claim B8, wherein the amount of output level compensation is determined based on the high frequency channel level.

B14. The method of claim B8, wherein the slope adjustment is determined based on the low frequency channel level.

C1. A frequency band selector that can be inserted into the signal transmission line of a CATV system in your area:

At least two sets of signal paths coming between the provider side and the user side, each set of signal paths comprising two discrete signal paths, a forward path allowing downstream bandwidth to pass from the provider side to the user side, Two or more signal path sets for allowing upstream bandwidth to pass from the user side to the provider side, wherein the forward path and the return path are separated by different cutoff transmission frequencies for each of the signal path sets; And

And a switch controller having at least two discrete switch positions, selecting one switch position as a result of the information signal, each switch position comprising a switch controller corresponding to each of a set of signal paths.

C2. C1, comprising: a supplier side filter set comprising at least two frequency band dividing devices which can be selected by a supplier side switch set; And

A user-side filter set comprising at least two frequency band splitters that can be selected by the user-side switch set,

And said supplier-side switch set and said user-side switch set are operated by a switch controller.

C3. 2. The frequency band selector of C2, wherein the supplier side switch set comprises a supplier side downstream switch and a supplier side upstream switch, and the user side switch set comprises a user side downstream switch and a user side upstream switch.

C4. The frequency band selection device of claim 1, wherein the information signal is a continuous sound.

C5. The frequency band selection device of claim 1, wherein the information signal is an encrypted operation signal.

C6. 2. The frequency band selection device of C2, wherein one of the frequency band dividing devices in each of the supplier-side filter set and the user-side filter set is configured to separate the upstream bandwidth from the downstream bandwidth according to DOCSIS-1.

C7. 2. The frequency band selector of C2, wherein one of the frequency band dividing devices in each of the supplier-side filter set and the user-side filter set is configured to separate the upstream bandwidth from the downstream bandwidth according to DOCSIS-2.

C8. 2. The frequency band selection device of C2, wherein one of the frequency band dividing devices in each of the supplier-side filter set and the user-side filter set is configured to separate the upstream bandwidth from the downstream bandwidth according to DOCSIS-3.

C9. 2. A frequency band selector according to C1, comprising three or more sets of signal paths and three or more discrete switch position data transfer protocols.

C10. As a method for changing the CATV frequency band in the CATV service user area:

A frequency band selector is provided in a user area, and the frequency band selector is:

At least two sets of signal paths coming between the provider side and the user side of the frequency band selector, each set of signal paths comprising two discrete signal paths, such that the forward path allows downstream bandwidth to pass from the provider side to the user side At least two signal path sets such that a return path allows an upstream bandwidth to pass from the user side to the provider side, wherein the forward path and the return path are separated by different cutoff transmission frequencies for each of the signal path sets; And

Having at least two discrete switch positions, selecting one switch position as a result of the information signal, each switch position comprising a switch controller corresponding to each of the signal path sets; And

A method for changing a CATV frequency band comprising operating a switch controller in the desired signal path of each set of signal paths as a result of an information signal.

C11. C10, comprising: a supplier side filter set comprising at least two frequency band splitting devices selectable by a supplier side switch set; And

Further comprising a user side filter set comprising at least two frequency band splitting devices selectable by the user side switch set;

And said supplier-side switch set and user-side switch set are operated by a switch controller to the desired signal path of each set of signal paths.

C12. In C11, the supplier-side switch set includes a supplier-side downstream switch and a supplier-side upstream switch, and the user-side switch set includes a user-side downstream switch and a user-side upstream switch. How to change.

C13. C10. The method of claim 10, wherein the information signal is a continuous sound.

C14. C10. The method of claim 10, wherein the information signal comprises an encrypted operational signal.

C15. The method according to C11, wherein one of the frequency band dividing devices in each of the supplier-side filter set and the user-side filter set is configured to separate the upstream bandwidth from the downstream bandwidth according to DOCSIS-1.

C16. The method according to C11, wherein one of the frequency band dividing devices in each of the supplier-side filter set and the user-side filter set is configured to separate the upstream bandwidth from the downstream bandwidth according to DOCSIS-2.

C17. The method according to C11, wherein one of the frequency band dividing devices in each of the supplier-side filter set and the user-side filter set is configured to separate the upstream bandwidth from the downstream bandwidth according to DOCSIS-3.

C18. A method according to C10 for allowing a greater number of data transfer protocols, including three or more signal path sets and three or more discrete switch locations.

D1. A downstream bandwidth regulator that can be inserted into a transmission line of a CATV system in and near the user's area,

A forward path extending over at least a portion of the distance between the provider side connector and the user side connector;

A coupler coupled within the forward path, the coupler providing a secondary path;

A tuner coupled to the coupler, the tuner being capable of tuning based on an input from a microprocessor, the tuner providing a tuner output of the selected channel, wherein the selected channel is at least one of a high frequency channel and a low frequency channel. Bar tuner;

A channel analyzer coupled to the output of the tuner, the channel analyzer providing a modulation output to a microprocessor, wherein the modulation output differs when the selected channel is analog modulation and when the selected channel is digital modulation;

A slope adjustment circuit coupled in a forward path between a coupler and a supplier side connector, the slope adjustment circuit comprising: a slope adjustment circuit adjustable based on a slope control output provided by a microprocessor; And

An output compensation circuit electrically connected in the forward signal path between the coupler and the supplier side connector, the output bandwidth adjusting device comprising an output compensation device that is adjustable based on the level control output from the microprocessor.

D2. The downstream bandwidth adjuster of D1, wherein the microprocessor includes one or more control modes used to change the slope control input and the level control input.

D3. In D2, the first control mode comprises at least one input between the slope control input and the level control input based on one low channel level from each of the one or more low frequency channels and one high channel level from each of the one or more high frequency channels. Downstream bandwidth regulator, characterized in that the change.

D4. In D2, the first control mode changes at least one of the slope control input and the level control input based on one low channel level from a single low frequency channel and one high channel level from a single high frequency channel. Downstream bandwidth regulator.

D5. 2. The apparatus of claim 3, wherein the second control mode changes at least one of the slope control input and the level control input based on the plurality of low channel level averages.

D6. 2. The apparatus of claim 3, wherein the second control mode changes at least one of the slope control input and the level control input based on the plurality of high channel level averages.

D7. The downstream bandwidth adjusting device of D5, wherein the first control mode is different in at least one of the slope control input and the level control input faster than in the second control mode.

D8. 12. The downstream bandwidth adjuster of D1, comprising one or more control modes for changing the slope control input by comparing one of the low channel level and the high channel level to respective target levels.

D9. 12. The downstream bandwidth adjuster of D8, wherein the control mode causes the level control input to be changed by comparing one of the low channel level and the high channel level with each target level.

D10. The downstream of D9, wherein the control mode selectively adds the digital channel offset to one of the first level and each target level before comparing one of the low channel level and the high channel level with each target level. Bandwidth Regulator.

D11. The downstream bandwidth adjuster of D9, wherein the control mode selectively subtracts the digital channel offset from the target level before comparing one of the low channel level and the high channel level with each target level.

D12. At D1, comprising at least one control mode for causing the microprocessor to change the slope control input to the slope adjustment circuit by comparing the low channel level from the at least one low frequency channel with each target level. Downstream bandwidth regulator.

D13. D12. The apparatus of claim 12, further comprising one or more control modes that cause the microprocessor to change the level control input by comparing the high frequency channel levels of the one or more high frequency channels with respective target levels.

D14. The downstream bandwidth adjuster of D1, comprising one or more calibration memory locations for each of the one or more low frequency channels and each of the one or more high frequency channels.

D15. The downstream bandwidth adjuster of D12, wherein the microprocessor includes a target memory location for each of the one or more low frequency channels and for each of the one or more high frequency channels.

D16. A method for adjusting downstream bandwidth in or near a CATV service user area,

Start the first mode, the first mode:

Tune to an initial high frequency channel from the downstream bandwidth;

Obtain high channel modulation and high channel level from the initial high frequency channel;

Tune to an initial low frequency channel from the downstream bandwidth;

Obtain low channel modulation and low channel level from the initial low frequency channel;

Provide a level adjustment amount of the downstream bandwidth; And

Providing a slope adjustment amount of the downstream bandwidth.

D17. In D16, the first mode is:

Obtain a first difference between the high channel level and each high channel target level; And

And further obtaining a second difference between the low channel level and each high channel target level.

D18. D17. The method of D17, further comprising changing at least one of the first and second differences based on an indication difference between the high channel modulation and the low channel modulation.

D19. In D17, the second mode is started after repeating the first mode step one or more times, and the second mode is:

Obtain high channel modulation and high channel level for each of the plurality of high frequency channels;

Obtain a high channel level average;

Obtain low channel modulation and low channel level for each of the plurality of low frequency channels;

Obtain a low channel level average;

Provide a level adjustment amount of the downstream bandwidth; And

Providing a slope adjustment amount of the downstream bandwidth.

D20. In D19, the second mode is:

Obtain a third difference between the average of the high channel levels and the average of each high channel target level; And

Obtaining a fourth difference between the low channel level average and each low channel target level average.

D21. In D19, the second mode is:

And returning to the first mode when the third and fourth differences exceed each predetermined threshold.

D22. In D18, an indication is provided to the microprocessor for each of the plurality of high frequency channels and each of the plurality of low frequency channels, such that the indication indicates whether each channel is being transmitted from the supplier,

Include the high channel level only for the high frequency channels where the average of the high channel level is shown to be transmitted from the supplier, and

Wherein the average of the low channel levels includes the low channel level only for the low frequency channels indicated to be transmitted from the provider.

F1. As a measuring device for measuring upstream bandwidth:

A return path extending at least a portion of the distance between the provider side connector and the user side connector;

A coupler coupled within the return path to provide a second path;

Detection circuitry electrically connected downstream of the coupler;

A level detector electrically connected downstream of the detection circuit; And

A microprocessor electrically connected downstream of the level detector, the microprocessor comprising a first buffer and a second buffer.

F2. The measuring device for measuring upstream bandwidth of F1, further comprising a nonlinear amplifier electrically connected downstream of the level detector and upstream of the microprocessor.

F3. For F1, the first buffer is a serial peak buffer, comprising a value associated with the voltage output of the level detector, and the second buffer is an average buffer, comprising one or more averages of the values located in the serial peak buffer. A measuring device for measuring upstream bandwidth, characterized in.

F4. The measuring device for measuring upstream bandwidth of F1, further comprising a high pass filter electrically connected between the coupler and the RF detection circuit.

F5. The measuring device for measuring upstream bandwidth of F1, wherein the detection circuit comprises an amplifier and a detector, wherein the detector converts the frequency dependent voltage flow into a first time dependent voltage flow.

F6. The upstream bandwidth of F5, wherein the detection circuit further comprises a low pass amplifier electrically connected downstream of the detector, wherein the low pass amplifier amplifies the long period voltage in the first voltage flow greater than the short period voltage. Measuring device for measuring the

F7. For F1, the level detector comprises one or more diodes, one or more resistors, and one or more capacitors, the capacitors being electrically connected downstream of the one or more diodes, the capacitors being the most suitable for the expected upstream bandwidth expected. Measuring device for measuring upstream bandwidth, characterized by having a discharge time constant of more than 10 times greater than the increased voltage of a low period.

F8. The measuring device for measuring upstream bandwidth of F3, wherein the series peak buffer is initially filled with a seed value and the seed value is within a range of expected values associated with a nonlinear amplifier voltage output.

F9. The apparatus of claim F2, wherein the nonlinear amplifier provides relatively less amplification from the level detector voltage flow to the higher voltage than from the voltage detector's voltage flow to the low voltage.

F10. The measuring device of claim 1, wherein the coupler is electrically connected between a user side deplexer filter and a supplier side deplexer filter.

F11. The apparatus of F1, further comprising an output device for storing, reviewing or analyzing by an engineer for optimal upstream bandwidth adjustment, wherein the output device is a monitor, memory device, network monitoring location, hand-held device. And a measuring device for measuring upstream bandwidth, characterized in that at least one of the printers.

F12. For F1, the microprocessor further comprises a memory location for the high voltage threshold and the low voltage threshold, wherein the high voltage threshold and the low voltage threshold are each calculated from a value located in the average buffer. Measuring device for measuring the

F13. As a way to get level data for upstream bandwidth:

Converting the frequency dependent voltage flow into a time dependent voltage flow comprising an increased voltage period;

Amplify and maintain a period of increased voltage using a low pass amplifier and a peak detector;

Record the peak values from the multiple voltage series in the output voltage flow, each series beginning with a measured voltage level above the high voltage limit and ending with a measured voltage level passing below the low voltage limit;

Locate the peak value in the first buffer;

Periodically calculating a first buffer average that is an average of peak values in the first buffer;

Locate each of the first buffer averages in the second buffer;

Periodically calculating a second buffer average, which is the average of the first buffer averages in the second buffer; And

Outputting at least one level average of at least one first buffer and at least one second buffer average of the output device for review by a technician for the purpose of adjusting the upstream bandwidth.

F14. For F13, before placing the peak values in the first buffer, fill the first buffer with a seed value, wherein the seed value is within an expected range of the peak value, the level data for upstream bandwidth. How to get it.

F15. The method of F13, further comprising calculating each of the high voltage limit value and the low voltage limit value based on a first buffer average located in the second buffer.

F16. Further comprising nonlinearly amplifying the period of the increased voltage such that the low voltage is increased to a magnitude greater than the high frequency to generate an output voltage flow. Way.

G1. As a device for adjusting upstream bandwidth:

A return path extending at least a portion of the distance between the provider side connector and the user side connector;

A coupler coupled within the return path to provide a second path;

Detection circuitry electrically connected downstream of the coupler;

A level detector electrically connected downstream of the detection circuit;

A microprocessor electrically connected downstream of the level detector, comprising a first buffer and a second buffer; And

And a variable signal level adjuster electrically connected upstream from the coupler in the return path, wherein the variable signal level adjuster is controlled by a microprocessor.

G2. The apparatus of G1, further comprising a nonlinear amplifier electrically connected downstream of the level detector and upstream of the microprocessor.

G3. For G1, wherein the first buffer is a serial peak buffer and includes a value associated with the voltage output of the level detector, and the second buffer is an average buffer and includes one or more averages of values located in the serial peak buffer. Characterized in that the device for adjusting the upstream bandwidth.

G4. The apparatus of G1, further comprising a high pass filter electrically connected between the coupler and the RF detection circuit.

G5. The apparatus of G1, wherein the detection circuit comprises an amplifier and a detector, wherein the detector converts the frequency dependent voltage flow into a first time dependent voltage flow.

G6. G5, wherein the detection circuit further comprises a low pass amplifier electrically connected downstream of the detector, wherein the low pass amplifier amplifies the long period voltage in the first voltage flow greater than the short period voltage. Apparatus for adjusting upstream bandwidth.

G7. For G1, the level detector comprises one or more diodes, one or more resistors, and one or more capacitors, the capacitors being electrically connected downstream of the one or more diodes, the capacitors being the most corresponding to the expected desired upstream bandwidth. A device for adjusting upstream bandwidth, characterized in that it has a discharge time constant that is at least 10 times greater than the increased voltage of a low period.

G8. 2. The apparatus of G3, wherein the series peak buffer is initially filled with seed values, wherein the seed values are within an expected range of values associated with a nonlinear amplifier voltage output.

G9. 2. The apparatus of G2, wherein the nonlinear amplifier provides relatively less amplification from the level detector voltage flow to the higher voltage than from the voltage detector's voltage flow to the low voltage.

G10. 2. The apparatus of G1, wherein the coupler is electrically connected between a user side deplexer filter and a supplier side deplexer filter.

G11. In G1, the microprocessor further comprises a memory location for the high voltage threshold and the low voltage threshold, wherein the high voltage threshold and the low voltage threshold are each calculated from a value located in the average buffer. Apparatus for adjusting upstream bandwidth.

G12. 10. The apparatus of G1, further comprising a setback timer.

G13. As a method for adjusting upstream bandwidth:

Converting the frequency dependent voltage flow into a time dependent voltage flow comprising an increased voltage period;

Amplify and maintain a period of increased voltage using a low pass amplifier and a peak detector;

Record the peak values from the multiple voltage series in the output voltage flow, each series beginning with a measured voltage level above the high voltage limit and ending with a measured voltage level passing below the low voltage limit;

Locate the peak value in the first buffer;

Periodically calculate a first buffer average;

Locate each of the first buffer averages in the second buffer;

The first buffer average is one of the above and below a predetermined value range, and the predetermined value range is one of a positive upper variable amount and a negative lower variable amount among the first buffer averages located in the second buffer;

Adding an attenuation increment to an upstream bandwidth when a first buffer is greater than the predetermined range of values.

G14. The method of G13, wherein before placing the peak values in the first buffer, the first buffer is filled with a seed value and the seed value is within an expected range of the peak value.

G15. The method of G13, further comprising calculating each of the high voltage limit value and the low voltage limit value based on a first buffer average located in the second buffer.

G16. The method of G13, further comprising nonlinearly amplifying the period of increased voltage such that the low voltage is increased to a magnitude greater than the high frequency to generate an output voltage flow.

G17. G13, further comprising reducing the attenuation increment for the upstream bandwidth when a predetermined time has elapsed after completing at least one of recording the peak value and calculating the first buffer average. Method for adjusting upstream bandwidth.

Claims (13)

A return path extending at least a portion of the distance between the provider side connector and the user side connector;
A forward path extending at least a portion of the distance between the provider side connector and the user side connector;
An upstream section including a variable signal level adjuster coupled within the return path
A downstream section including a forward coupler coupled within the forward path; And
At least one microprocessor electrically connected upstream of the variable signal level adjustment device,
And the microprocessor reduces the amount of signal level adjustment applied to the return path in response to the reduction of the downstream bandwidth level at the forward coupler. The method of claim 1, wherein the upstream section is
A return coupler coupled within the return path to provide a secondary path;
A detection circuit electrically connected downstream of the return coupler; And
Further comprising a level detector electrically connected downstream of the detection circuit,
And the microprocessor is electrically connected downstream of the level detector. 3. The apparatus of claim 2, wherein the downstream section includes a tuner tunable based on input from the microprocessor and coupled to the forward coupler;
The tuner provides a tuner output of the selected channel, wherein the selected channel is at least one of a high frequency channel and a low frequency channel. 4. The apparatus of claim 3, wherein the microprocessor includes one or more control modes for comparing one of the low channel level and the high channel level with a respective target level. . 5. The microprocessor of claim 4, wherein the microprocessor includes a level threshold, wherein a difference between one of the lower channel level and the higher channel level and each target level is compared with the level threshold. For adjusting the overall bandwidth of a CATV system. 2. The apparatus of claim 1, wherein the upstream and downstream sections use respective microprocessors of these sections themselves, the microprocessors having a communication link therebetween. . 2. The apparatus of claim 1, wherein the upstream portion and the downstream section use the same microprocessor. Adding at least one attenuation increment to the upstream bandwidth;
Measuring a downstream bandwidth of the first level; And
Removing at least a portion of the at least one attenuation increment in response to the downstream bandwidth of the first level. The method of claim 8, further comprising: measuring a downstream bandwidth of the second level for a predetermined time before the downstream bandwidth of the second level is measured downstream of the first level;
Comparing the second level of downstream bandwidth with each target step to obtain a second difference;
Comparing the first level downstream bandwidth with each target step to obtain a first difference; And
Removing said portion of said at least one attenuation increment if said first difference and said second difference change by a difference that is greater than a predetermined threshold. 10. The method of claim 9, wherein the predetermined threshold is at least a portion of the expected variation, the expected variation including those associated with at least one of periodic temperature, humidity, and daylight. . 12. The method of claim 10, wherein the predetermined threshold value changes over time between the measurement of the second level and the measurement of the first level. The method of claim 8, wherein the first mode is initiated.
Tuning from the downstream bandwidth to the initial high frequency channel;
Obtaining a high channel modulation and a high channel level from the initial high frequency channel;
Tuning from the downstream bandwidth to an initial low frequency channel;
Obtaining low channel modulation and low channel steps from the initial low frequency channel;
Providing a level adjustment amount of downstream bandwidth; And
Initiating a first mode comprising providing a slope adjustment amount of a downstream bandwidth; And
Starting the second mode after at least one iteration of the steps of the first mode,
The second mode is
Obtaining a high channel modulation and a high channel level for each of the plurality of high frequency channels;
Obtaining an average of the high channel levels;
Obtaining a low channel modulation and a low channel level for each of the plurality of low frequency channels;
Obtaining a low channel level average;
Providing a level adjustment amount of downstream bandwidth;
Providing a slope adjustment amount of downstream bandwidth;
Obtaining a third difference between the average of the high channel levels and the average of each high channel target level;
Obtaining a fourth difference between the average of the low channel levels and the average of each low channel target level;
Returning to the first mode when at least one of the third and fourth differences exceeds a respective predetermined threshold value; And
Removing the portion of the at least one attenuation increment when returning from the second mode to the first mode. The method of claim 12,
Providing the microprocessor with an identifier for each of the plurality of high frequency channels and each of the plurality of low frequency channels,
The identifier indicates whether each channel is received from one provider,
The average of the low channel levels includes a high channel level only for high frequency channels that are found to be being transmitted from the provider,
And wherein said average of said low channel levels includes low channel levels only for low frequency channels identified as being received from said provider.

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