Apparatus and method for optimal frequency planning in frequency division multiplexing transmissions

US 5,295,138 A
Filed: 04/21/1992
Issued: 03/15/1994
Est. Priority Date: 04/21/1992
Status: Expired due to Fees

First Claim

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1. A method for operating a frequency division multiplexing (FDM) transmitter within a common communication channel, wherein a plurality of signals are transmitted through separate channels via a plurality of modulators having corresponding carrier frequencies, by adjusting each carrier frequency through the steps comprising:

(a) randomly allocating each separate channel within the available bandwidth to provide an initial set of separate channel allocation and corresponding carrier frequencies;

(b) measuring carrier to intermodulation ratio(C/IM) on each channel;

(c) removing the worst channel with the lowest carrier to intermodulation ratio (C/IM) when said worst channel can be moved or removing a movable channel previously nonremoved when said worst channel cannot be moved;

(d) examining all possible single-channel insertions in available unoccupied bandwidth and selecting an insertion which produces the largest minimum carrier to intermodulation ratio (C/IM);

(e) repeating steps (b) through (d) until no improvement in minimum carrier intermodulation ratio (C/IM) can be achieved for said random allocation of separate channels;

(f) repeating steps (a)-(e) for plurality of initial random channel allocations, to achieve a set of separate channel allocations among said initial random channel allocations with largest minimum carrier to intermodulation ratio (C/IM); and

(g) tuning the modulators corresponding to each carrier frequency in said frequency division multiplexing (FDM) transmitter according to said set of separate channel allocation.

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Abstract

A method and apparatus for operating a frequency division multiplexing (FDM) transmitter within a common communication channel is disclosed. The carrier frequency for each separate channel is adjusted for minimizing intermodulation interference. The system randomly allocates each separate channel within the available bandwidth to provide an initial set of separate channel allocation and corresponding carrier frequencies. Thereafter carrier to intermodulation ratio (C/IM) on each channel is measured and the worst channel with the lowest carrier to intermodulation ratio (C/IM) is removed. The system then repeatedly inserts a channel in available unoccupied bandwidth to produce the largest minimum carrier to intermodulation ratio (C/IM). The deletion and insertion continues until no improvement in minimum carrier to intermodulation ratio (C/IM) can be achieved for said random allocation of separate channels. The selected set of separate channel allocations is further fine-tuned by deleting the worst channel with minimum carrier to intermodulation ratio (C/IM) and deleting one other channel from said separate channel allocations to provide a particular dual channel deletion. The system then repeatedly inserts two channels in available unoccupied bandwidth which produces the largest minimum carrier to intermodulation ratio (C/IM). The system continues on dual deletion and insertion until no improvement in minimum carrier to intermodulation ratio (C/IM) can be achieved for said random allocation of separate channels. The carrier frequencies are then tuned according to said set of separate channel allocation.

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8 Claims

1. A method for operating a frequency division multiplexing (FDM) transmitter within a common communication channel, wherein a plurality of signals are transmitted through separate channels via a plurality of modulators having corresponding carrier frequencies, by adjusting each carrier frequency through the steps comprising:
- (a) randomly allocating each separate channel within the available bandwidth to provide an initial set of separate channel allocation and corresponding carrier frequencies;
  
  (b) measuring carrier to intermodulation ratio(C/IM) on each channel;
  
  (c) removing the worst channel with the lowest carrier to intermodulation ratio (C/IM) when said worst channel can be moved or removing a movable channel previously nonremoved when said worst channel cannot be moved;
  
  (d) examining all possible single-channel insertions in available unoccupied bandwidth and selecting an insertion which produces the largest minimum carrier to intermodulation ratio (C/IM);
  
  (e) repeating steps (b) through (d) until no improvement in minimum carrier intermodulation ratio (C/IM) can be achieved for said random allocation of separate channels;
  
  (f) repeating steps (a)-(e) for plurality of initial random channel allocations, to achieve a set of separate channel allocations among said initial random channel allocations with largest minimum carrier to intermodulation ratio (C/IM); and
  
  (g) tuning the modulators corresponding to each carrier frequency in said frequency division multiplexing (FDM) transmitter according to said set of separate channel allocation.
- View Dependent Claims (2, 3, 4)
- - 2. The method according to claim 1 wherein said step (b) further comprises:
    - assigning first and second type interferences in said carrier to interference ratio (C/IM) wherein said first type interference is defined by (f_i +f_i+1 -f_i+2) and the second type is 2f_i -f_i+1), where f_i+1 and f_i+2 are any one of the separate carrier frequencies.
  - 3. The method according to claim 2, further comprising the step of Nyquist shaping each separate signal to be transmitted by said frequency division multiplexing (FDM) transmitter.
  - 4. The method according to claim 1, wherein said set of separate channel allocations is further fine-tuned before said step (g) of tuning carrier frequencies, said method comprising:
    - (h) deleting the worst channel with minimum carrier to intermodulation ratio (C/IM) if said worst channel can be removed or deleting a moveable channel instead of the worst channel if said worst channel cannot be removed;
      
      (i) deleting one other movable channel from separate channel allocations to provide a particular dual channel deletion;
      
      (j) inserting two channels in available unoccupied bandwidth which produces the largest minimum carrier to intermodulation ratio (C/IM); and
      
      (k) repeating steps (h) through (j) until no improvement in minimum carrier to intermodulation ratio (C/IM) can be achieved for said random allocation of separate channels.

5. A frequency planning system for adjusting carrier frequencies in a frequency division multiplexing (FDM) transmitter wherein a plurality of signals are transmitted through separate channels via a plurality of modulators having corresponding carrier frequencies comprising:
- (a) a microprocessor for controlling the operation of said frequency planning system;
  
  (b) random channel allocating means randomly allocating each separate channel within the available transmission bandwidth to provide initial set of separate channel allocation and corresponding carrier frequencies;
  
  (c) a measuring means for determining carrier to intermodulation ratio(C/IM) on each channel so that the worst channel with the lowest carrier to intermodulation ratio (C/IM) is derived;
  
  (d) a channel removing means coupled to said measuring means for removing the worst channel with the lowest carrier to intermodulation ratio (C/IM) when said worst channel can be moved, said removing means, removing a movable channel previously not removed when said worst channel can not be removed;
  
  (e) a channel inserting means coupled to said channel removing means for repetitively inserting a channel allocation from available unoccupied bandwidth such that a channel allocation with the largest minimum carrier to intermodulation ratio (C/IM) is derived said removing means and said inserting means repetitively removing and inserting channel allocations until no improvement in minimum carrier intermodulation ratio (C/IM) can be achieved for said random allocation of separate channels;
  
  (f) means for providing a plurality of said random channel allocation sets;
  
  (g) means for deriving a best set of separate channel allocations among said initial random channel allocations with largest minimum carrier to intermodulation ratio (C/IM); and
  
  (h) a tuner means for tuning the modulators corresponding to each carrier frequency in said frequency division multiplexing (FDM) transmitter according to said set of separate channel allocation.
- View Dependent Claims (6, 7, 8)
- - 6. The system according to claim 5, wherein said measuring means derives said carrier to intermodulation (C/IM) ratio by computing first and second type interferences wherein said first type interference is defined by (f_i +f_i+1 -f_i+2) and the second type is defined by (2f_i -f_i+1), where f_i, f_i+2 are any one of the separate carrier frequencies.
  - 7. The system according to claim 6, further comprising a means for Nyquist shaping each separate signal to be transmitted by said frequency division multiplexing (FDM) transmitter.
  - 8. The system according to claim 5 wherein said best set of separate channel allocations is further fine-tuned before said tuner means tunes carrier frequencies, wherein said channel removing means further removing the worst channel with minimum carrier to intermodulation ratio (C/IM) if said worst channel can be removed from said best set of separate channel allocations said channel removing means removing a moveable channel as the worst channel when said worst channel with minimum carrier to intermodulation ratio (C/IM) cannot be removed;
    - said channel removing means repetitively deleting one other moveable channel from set separate channel allocations to provide the particular dual channel deletion;
      
      said channel inserting means further inserting two channels in available unoccupied bandwidth for each said channel deletion, until no improvement in minimum carrier to intermodulation ratio (C/IM) can be achieved for said best set of separate channel allocation.

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Current Assignee
Stellar One Corp.
Original Assignee
Northwest Starcan Limited Partnership
Inventors
Gu, Goson, Greenberg, A. Frederick, Hatcher, G. Stephen
Primary Examiner(s)
Olms, Douglas W.
Assistant Examiner(s)
HSU, ALPUS

Application Number

US07/871,893
Time in Patent Office

693 Days
Field of Search

370/18, 370/19, 370/20, 370/57, 370/69.1, 370/120, 370/121, 370/123, 370/70, 370/71, 370/75, 370/76, 370/118, 370/122, 375/1, 375/58, 375/60, 455/12.1, 455/17, 455/62, 455/63, 455/67.1, 455/67.3, 455/115, 455/119, 455/120, 455/125
US Class Current

370/344
CPC Class Codes

H04J 1/12 Arrangements for reducing c...

H04Q 11/02 for frequency-division mult...

Apparatus and method for optimal frequency planning in frequency division multiplexing transmissions

First Claim

11 Assignments

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Accused Products

Abstract

59 Citations

8 Claims

Specification

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Apparatus and method for optimal frequency planning in frequency division multiplexing transmissions

First Claim

11 Assignments

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0 Petitions

Subscription Required

Accused Products

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Abstract

59 Citations

8 Claims

Specification

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Use Cases

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Others