JP3830694B2 - Tone detection device, facsimile device and communication terminal device - Google Patents

Description

となる。
また、乗算器Ｍ２１の出力は、

となる。
【００７５】
したがって、図９において、周波数変換器２５から帯域通過フィルタ２０ａに入力される信号は、周波数変換器２５に入力される検出対象信号の周波数が、＋ｆ０だけシフトされた信号と、−ｆ０だけシフトされた信号が合成されたものとなる。
【００７６】
一方、帯域通過フィルタ２０ａは、図１０に実線で示す特性であるため、周波数変換器２５に入力される検出対象信号が、図１０に一点鎖線で示すトーン検出範囲内にあれば、周波数変換器２５により＋ｆ０だけシフトされた信号成分については、図１０に実線で示す帯域通過フィルタ２０ａの通過帯域外になるため大きく減衰されるものの、周波数変換器２５により−ｆ０だけシフトされた信号成分については、図１０に実線で示す帯域通過フィルタ２０ａの通過帯域内になるためほとんど減衰されることなく、帯域通過フィルタ２０ａから出力される。
【００７７】
つまり、周波数変換器２５と帯域通過フィルタ２０ａにより構成される仮想的な帯域通過フィルタの中心周波数は、帯域通過フィルタ２０ａの特性を決定付ける、フィルタ係数記憶部２１に記憶されたフィルタ係数群の値が固定されていても、周波数記憶部２７に周波数シフト量を設定するのみで、中心周波数以外の通過帯域幅等のその他の特性を固定したまま、容易に変更することができる。なお、周波数記憶部２７への周波数シフト量の設定は、システム制御部２が、装置出荷時や、装置設置時に作業員やサービスマンにより行われる操作表示部９からの所定の操作により入力された周波数シフト量を、周波数記憶部２７に書き込むことにより行われる。
【００７８】
したがって、装置出荷時に仕向地に応じたトーン信号の周波数を周波数記憶部２７に設定するのみで、各仕向地ごとのトーン信号の周波数の違いに対応することが可能となり、帯域通過フィルタ２０ａのフィルタ係数群を多数予め記憶しておいて、そのうちのいずれかのフィルタ係数群を各仕向地ごとのトーン信号の周波数の違いに応じて設定する場合に比較して、多数のフィルタ係数群の記憶のためのメモリを節約することができる。
【００７９】
次に、図９に示した本発明に係るトーン検出部１０ａの変形例について、図１２に示す。
【００８０】
図１２において、図９に示したトーン検出部１０ａと異なる点は、周波数変換器２５と比較器２３との間の帯域通過フィルタ２０ａ及び電力積分器２２に代えて、帯域通過フィルタ２０ｂ及び電力積分器２２ａと、帯域通過フィルタ２０ｃ及び電力積分器２２ｂとを配置すると共に、差分回路２８を配置した点である。帯域通過フィルタ２２ｂ及び２０ｃは、帯域通過フィルタ２０ａと同一のものであるが、フィルタ計数記憶部２１に記憶されたフィルタ係数により設定されるフィルタ特性が異なる。電力積分器２２ａ及び２２ｂは、電力積分器２２と同一のものである。
【００８１】
周波数変換器２５により周波数変換された検出対象の入力信号は帯域通過フィルタ２２ｂ及び帯域通過フィルタ２２ｃに入力される。帯域通過フィルタ２２ｂに入力された信号は、帯域通過フィルタ２２ｂのフィルタ特性に応じた周波数成分が遮断され、それ以外の周波数成分が電力積分器２２ａに入力され、電力積分器２２ａは、帯域通過フィルタ２０ｂから入力された信号のレベルを検出して差分回路２８に入力する。帯域通過フィルタ２２ｃに入力された信号は、帯域通過フィルタ２２ｃのフィルタ特性に応じた周波数成分が遮断され、それ以外の周波数成分が電力積分器２２ｂに入力され、電力積分器２２ｂは、帯域通過フィルタ２０ｃから入力された信号のレベルを検出して差分回路２８に入力する。
【００８２】
差分回路２８は、電力積分器２２ａから入力される信号レベルの、電力積分器２２ｂから入力される信号レベルとの差分レベルを比較器２３に入力する。比較器２３は、差分回路２８から入力されるレベルを、しきい値記憶２４に設定されたしきい値と比較して、その設定されたしきい値以上であれば、入力信号がトーン信号であるとの判定結果を出力する。
【００８３】
ここで、図１２に示すトーン検出部１２ａにおける検出例について説明する。いま、検出しようとするトーン信号が１３００Ｈｚ±５０Ｈｚであるとする。その場合、入力信号がＤＴＭＦ信号で、「２」に対応するもの（ ６９７Ｈｚと１３３６Ｈｚとの組合せ）であったり、「５」に対応するもの（ ７７０Ｈｚと１３３６Ｈｚとの組合せ）であったり、「８」に対応するもの（ ８５２Ｈｚと１３３６Ｈｚとの組合せ）であったりした場合、図４に示したような従来のトーン検出部１０ａや、図９に示したトーン検出部１０ａによる検出では、それら各ＤＴＭＦ信号の１３３６Ｈｚの成分がしきいレベル以上で検出されると、トーン信号ありと検出されてしまうが、実際はＤＴＭＦ信号であるため、誤検出となってしまう。そのため、相手先装置側でブッシュボタンを押したりしてＤＴＭＦ信号が回線にのった場合、そのＤＴＭＦ信号を、通信プロトコルのやりとり等のために使用される１３００Ｈｚ±５０Ｈｚのトーン信号と誤検出してしまって、通信動作に支障がでてしまう。
【００８４】
そのようなＤＴＭＦ信号をトーン信号と誤検出しないためには、１３３６Ｈｚの信号が１３００Ｈｚ±５０Ｈｚの範囲内の信号として検出された場合でも、同時に、６９７Ｈｚ、７７０Ｈｚ、８５２Ｈｚの各信号が検出された場合には、トーン信号として検出しないようにすればよい。
【００８５】
そこで、図１２に示すトーン検出部１０ａでは、周波数記憶部２７に設定する周波数として１３００Ｈｚを設定して入力信号を１３００Ｈｚ分だけシフトする。そして、フィルタ係数記憶部２１に設定する、帯域通過フィルタ２０ｂ用のフィルタ係数を、帯域通過フィルタ２０ｂのフィルタ特性が、図１３（ａ）に示すように、±５０Ｈｚの周波数範囲の信号成分のみを通過するように係数設定する。また、フィルタ係数記憶部２１に設定する、帯域通過フィルタ２０ｃ用のフィルタ係数を、帯域通過フィルタ２０ｃのフィルタ特性が、図１３（ｂ）に示すように、±５２５Ｈｚ±１００Ｈｚの周波数範囲の信号成分のみを通過するように係数設定する。
【００８６】
それにより、入力信号の周波数成分のうちの１３３６Ｈｚの成分が１３００Ｈｚシフトされた＋３６Ｈｚの信号が、±５０Ｈｚの範囲内の信号として帯域通過フィルタ２０ｂを通過し、それにより電力積分器２２ａから差分回路２８の「＋」入力に一定レベルの入力があった場合でも、同時に、入力信号の周波数成分のうちの６９７Ｈｚ、７７０Ｈｚまたは８５２Ｈｚの成分が、それぞれ１３００Ｈｚシフトされて得られた、−６０３Ｈｚ、−５３０Ｈｚ、または、−４４８Ｈｚの信号が、±５２５Ｈｚ±１００Ｈｚの範囲内の信号として帯域通過フィルタ２０ｃを通過し、それにより電力積分器２２ｂから差分回路２８の「−」入力に一定レベルの入力があるため、差分回路２８から出力される信号レベルはほとんど０レベルとなり、比較器２３によりトーン信号と判定されることがなくなる。
【００８７】
これにより、検出しようとするトーン信号の周波数範囲の信号を含むＤＴＭＦ信号をトーン信号と誤検出することがなくなる。
【００８８】
次に、図１２に示すトーン検出部１０ａにおける別の検出例について説明する。
【００８９】
図１２に示すトーン検出部１０ａでは、周波数記憶部２７に設定する周波数として検出しようとするトーン信号の中心周波数を設定して入力信号をその中心周波数分だけシフトする。そして、フィルタ係数記憶部２１に設定する、帯域通過フィルタ２０ｂ用のフィルタ係数を、帯域通過フィルタ２０ｂのフィルタ特性が、図１４（ａ）に示すように、±ｆｃＨｚの周波数範囲の信号成分のみを通過するように係数設定する。また、フィルタ係数記憶部２１に設定する、帯域通過フィルタ２０ｃ用のフィルタ係数を、帯域通過フィルタ２０ｃのフィルタ特性が、図１４（ｂ）に示すように、 ±ｆｃＨｚの周波数範囲外の信号成分のみを通過するよう係数設定する。
【００９０】
それにより、入力信号の周波数成分のうちの、検出しようとするトーン信号の中心周波数分だけシフトされた±ｆｃＨｚの周波数範囲の成分の信号が、±ｆｃＨｚの範囲内の信号として帯域通過フィルタ２０ｂを通過し、それにより電力積分器２２ａから差分回路２８の「＋」入力に一定レベルの入力があった場合でも、同時に、 入力信号の周波数成分のうちの、検出しようとするトーン信号の中心周波数±ｆｃＨｚの範囲外の成分が、当該中心周波数分だけシフトされて得られた信号が、±ｆｃＨｚの範囲外の信号として帯域通過フィルタ２０ｃを通過し、それにより電力積分器２２ｂから差分回路２８の「−」入力に一定レベルの入力があるため、差分回路２８から出力される信号レベルはほとんど０レベルとなり、比較器２３によりトーン信号と判定されることがなくなる。
【００９１】
これにより、検出しようとするトーン信号の周波数範囲の信号を含むＤＴＭＦ信号等の信号をトーン信号と誤検出することがなくなる。また、帯域通過フィルタ２０ｃの特性が、検出しようとするトーン信号の周波数範囲外を通過させる単純な特性になるため、帯域通過フィルタ２０ｂ、２０ｃのフィルタ係数を少なくできその分フィルタ係数記憶部２１の記憶容量を節減することができる。
【００９２】
また、検出用周波数帯域ｆｃとして、例えば、ｆc＝±１０Ｈｚ、±５０Ｈｚ、±１００Ｈｚ、±１５０Ｈｚ、±２００Ｈｚ等から選択可能とし、ファクシミリ装置１は、トーン検出器１０ａに対してフィルタ係数値を設定するのではなく、上記の様にあらかじめ用意された検出周波数帯域を設定し、トーン検出器１０ａでは、各検出周波数帯域に対して、図１４に示す特性を生成する帯域通過フィルタ２０ｂ、２０ｃのフィルタ用係数値を選択使用するようにしてもよい。それにより、ファクシミリ装置１本体側が、全係数値を保持する必要がなくなり、誤検出の少ないトーン検出装置をメモリを増加する事なく実現することができる。
【００９３】
なお、以上説明した実施の形態においては、本発明に係るトーン検出装置を通信端末装置の１つであるファクシミリ装置に適用したが、本発明に係るトーン検出装置は、それに限らず、回線を介してその他のデータ通信を行うその他の通信端末装置に対しても同様に適用可能なものである。
【００９４】
【発明の効果】
請求項１に係る発明によれば、前記検出対象信号が、検出しようとするトーン信号の周波数範囲の一定レベル以上の信号成分を含むと同時に、検出しようとするトーン信号の周波数範囲の信号成分以外の信号成分を含むようなＤＴＭＦ信号等のトーン信号として検出してはならない信号であった場合には、前記信号差分手段の出力はほとんど０レベルなって前記検出対象信号は、トーン信号とは判定されなくなるため、検出しようとするトーン信号の周波数範囲の信号成分を含むがトーン信号ではない信号をトーン信号と誤検出することがなくなるという効果が得られる。
また、検出しようとするトーン信号の周波数範囲を通過する前記第１帯域通過フィルタと、検出しようとするトーン信号の周波数範囲外を通過する前記第２帯域通過フィルタとは、遮断周波数等が共通となるため、必要なフィルタ係数を減らすことができ、その分フィルタ係数記憶のためのメモリ容量を低減でき、また、前記第１及び第２帯域通過フィルタの遮断周波数を比較的容易に設定変更することが可能となる効果が得られる。
【００９５】
請求項２に係る発明によれば、請求項１に係る発明の効果をファクシミリ装置において得ることが可能となる効果が得られる。
【００９６】
請求項３に係る発明によれば、請求項１に係る発明の効果を通信端末装置において得ることが可能となる効果が得られる。
【図面の簡単な説明】
【図１】本発明の実施の形態に係るトーン検出装置を構成として含むファクシミリ装置のブロック構成を示す図である。
【図２】本発明の実施の形態に係るファクシミリ装置におけるファクシミリ送受信処理手順について示すフローチャートである。
【図３】図２と共に、本発明の実施の形態に係るファクシミリ装置におけるファクシミリ送受信処理手順について示すフローチャートである。
【図４】本発明に係るトーン検出部と比較される従来のトーン検出部の構成について示す図である。
【図５】図４に示すトーン検出部の帯域通過フィルタの特性について示す図である。
【図６】図４に示すトーン検出部の帯域通過フィルタの特性と、検出対象のトーン信号の周波数との関係について示す図である。
【図７】帯域通過フィルタの構成について示す図である。
【図８】電力積分器の構成について示す図である。
【図９】本発明に係るトーン検出部の構成について示す図である。
【図１０】図９に示すトーン検出部の帯域通過フィルタの特性等について示す図である。
【図１１】図９に示すトーン検出部における周波数変換器、発振器、及び、周波数記憶部の構成及び関係について示す図である。
【図１２】図９に示すトーン検出部の変形例について示す図である。
【図１３】図１２に示すトーン検出部の帯域通過フィルタの特性例について示す図である。
【図１４】図１２に示すトーン検出部の帯域通過フィルタの別の特性例について示す図である。
【符号の説明】
１ ファクシミリ装置
２ システム制御部
３ ＲＯＭ
４ ＲＡＭ
５ スキャナ
６ プロッタ
７ 画像メモリ
８ 符号化復号化部
９ 操作表示部
１０ モデム
１０ａ トーン検出部
１１ 網制御部
１２ システムバス
２０、２０ａ、２０ｂ、２０ｃ 帯域通過フィルタ
２１ フィルタ係数記憶部
２２、２２ａ、２２ｂ 電力積分器
２３ 比較器
２４ しきい値記憶部
２５ 周波数変換器
２６ 発振器
２７ 周波数記憶部
Ｔ１、Ｔ２ フィルタ定数
Ｋ１、Ｋ２、Ｋ３、Ｋ４、Ｋ５、Ｋ６、Ｋ１０、Ｋ１１ フィルタ係数
Ｍ１、Ｍ２、Ｍ３、Ｍ４、Ｍ５、Ｍ６、Ｍ１０、Ｍ１１、Ｍ１２、Ｍ１３、Ｍ２０、Ｍ２１ 乗算器
Ａ１，Ａ２、Ａ１０、Ａ１１、 加算器
Ｄ１、Ｄ２、Ｄ３、Ｄ４、Ｄ１０ ディレイライン[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a tone detection apparatus that detects a tone signal coming from a line, and a facsimile apparatus and a communication terminal apparatus to which the tone detection apparatus is applied.
[0002]
[Prior art]
In a communication terminal apparatus such as a facsimile apparatus, the line may have to be disconnected by detecting a busy sound signal coming from the line during communication.
[0003]
Specifically, in the facsimile apparatus, the other apparatus is communicating or talking at the time of automatic call, and the busy tone signal “Pup-Poo-Pu” from the subscriber exchange accommodating the facsimile apparatus is on the line. In some cases, the busy tone signal is detected, the line is released, and the line use efficiency is improved.
[0004]
Also, in a facsimile machine with an answering machine function, a voice message is received from a partner user that is received via the line when the user is away, and the partner user who has finished speaking speaks the handset of the partner device on-hook. When the line is disconnected, the busy tone signal sent from the subscriber exchange accommodating the facsimile device is detected, the voice message recording operation is terminated, and a useless signal (busy) In some cases, recording of sound signals) is not performed.
[0005]
Thus, a communication terminal apparatus that performs a predetermined operation as necessary when a busy signal on the line is detected must be able to accurately detect the busy signal on the line.
[0006]
In addition, it is necessary to be able to accurately detect a dial tone signal even when waiting for a response from the exchange by detecting a dial tone signal coming from the line when the phone is off-hooked. Also, by detecting a ringing tone signal coming from the line after sending a selection signal by dial pulse or DTMF signal off-hook when making a call, the ringing tone signal cannot be detected accurately even when checking the operation of the exchange. I must. Also, after sending a selection signal by going off-hook when making a call, the line must be disconnected by detecting the busy sound signal coming from the line because the other party specified by the selection signal is communicating There is.
[0007]
Since tone signals such as a busy tone signal, a dial tone signal, and a ringing tone signal sent to a certain communication terminal device via a line are sent from the subscriber exchange in which the communication terminal device is accommodated, A single tone signal can be accommodated in any subscriber switch in the circuit as long as the characteristics of the tone signals transmitted by all the subscriber switches are the same in all subscriber switches. The detection characteristic should be able to accurately detect the tone signal on the line.
[0008]
In a telephone line in Japan, a tone signal transmitted by a subscriber exchange is a signal of 400 ± 19 Hz, a dial tone signal is obtained by continuously transmitting a signal of 400 Hz ± 19 Hz, and a ringing tone signal is a signal of 400 Hz ± 19 Hz. Signal is modulated at a modulation rate of 85 ± 15% at a frequency of 15 Hz to 20 Hz, and the busy sound is a signal of 400 Hz ± 19 Hz with a make rate of 50% ± 10% and 60 cycles per minute ± Modulated by 20%.
[0009]
However, in some countries, the characteristics of the tone signal actually transmitted from the subscriber exchange in the circuit may not match the characteristics specified in that country. In addition to the characteristics, even if the tone signal detection characteristics of the tone detection device included in the communication terminal apparatus are set, the characteristics of the tone signal transmitted for each subscriber exchange in the line vary, and the communication terminal apparatus In some cases, the tone signal detection characteristic of the line does not match the characteristic of the tone signal transmitted by the subscriber exchange in which the communication terminal apparatus is accommodated, and the tone signal on the line cannot be detected.
[0010]
On the other hand, when the tone signal detection characteristics of the tone detector on the communication terminal side are wide, taking into account variations in the characteristics of the tone signal sent to each subscriber exchange in the line In some cases, communication signals on the line and voices of conversations are mistakenly detected as busy tone signals. Teshi In some cases, malfunctions may occur, such as the line being disconnected during communication, or the line being suddenly disconnected during recording of a voice message.
[0011]
Also, not only when accommodated in telephone line subscriber exchanges, but also when accommodated in extension line exchanges, if there are variations in the characteristics of tone signals transmitted by the exchanges within the extension line, similar problems may occur. Occurs.
[0012]
Thus, accurately detecting a tone signal coming from a line regardless of the installation location of the apparatus is important for normal communication.
[0013]
On the other hand, with the recent spread of information communication such as facsimile communication, it has been desired to further reduce the price of communication terminal devices such as facsimile devices, but communication terminal devices such as facsimile devices are used in countries where they are used. Therefore, different operation specifications are required for each destination.
[0014]
Therefore, in order to reduce the cost of the equipment and meet the demand for lower prices, the hardware related to different operation specifications for each destination is designed as a common design, and different settings are set for each destination. It meets the required operating specifications.
[0015]
It is not an exception even in the tone detection device applied to the communication terminal device, and parameters for detecting the detection target signal coming from the line as a tone signal, specifically, the setting of the frequency range and the threshold of the detection level Is changed by a program so that tone signals having different characteristics for each destination can be accurately detected.
[0016]
In the tone detector, as a circuit configuration for determining whether or not the detection target signal coming from the line is a tone signal, the detection target signal is input to a band pass filter in which an appropriate frequency range is set as the tone signal. In addition, there is a configuration in which the power of the signal output from the band pass filter is compared with a predetermined threshold level to determine whether or not it is a tone signal, and for each destination of the tone signal detection characteristics Is set by setting the characteristics of the band-pass filter or setting the predetermined threshold value.
[0017]
The characteristics of the band-pass filter, specifically, the center frequency, the pass bandwidth, the cutoff characteristic, etc. can be set by changing the setting of the filter coefficient group. However, for example, even when two of the center frequency, the pass bandwidth, and the cutoff characteristic are fixed and the remaining one is changed, it is necessary to change all the file coefficient values constituting the filter coefficient group. .
[0018]
In order to realize the desired filter characteristics of the bandpass filter, it is necessary to precisely calculate and actually verify each filter coefficient value constituting the filter coefficient group.
[0019]
[Problems to be solved by the invention]
Therefore, for each of a large number of filter characteristics that may be set for each destination, all corresponding filter coefficient groups are calculated, actually verified, and all filter coefficient groups are set in preparation for setting. There is a problem that it must be kept in memory.
[0020]
In addition to changing the setting of the filter characteristics for each destination, all filters corresponding to a number of filter characteristics can be used by service personnel to fine-tune various characteristics of the tone detection device at the actual installation location of each device. There is a problem that the coefficient group must be stored in the memory.
[0021]
Further, in the tone detection method using the band pass filter, in order to determine whether or not the detection target signal is a tone signal only based on the signal strength of the frequency component of the tone signal to be detected, for example, two types of frequencies are used. There is a problem that, when one of the frequencies constituting the combined DTMF signal is close to the frequency of the tone signal to be detected, the DTMF signal may be erroneously detected as a tone signal.
[0022]
The present invention has been made in view of such circumstances, and provides a tone detection apparatus, a facsimile apparatus, and a communication terminal apparatus that can flexibly change the tone signal detection characteristics with a small amount of memory consumption and can accurately detect a tone signal. The purpose is to do.
[0023]
[Means for Solving the Problems]
Claim 1 The tone detector described in 1 is a tone detector that detects whether or not the detection target signal coming from the line is a tone signal in a predetermined frequency range, and the frequency of the detection target signal is set by a set frequency shift amount. A frequency conversion means for shifting; a shift amount setting means for setting the frequency shift amount; By setting the filter coefficient group, Pass the predetermined frequency range of the frequency components of the input signal Set to characteristics, The signal from the frequency conversion means is input Ru A first bandpass filter; By setting the filter coefficient group, The frequency component of the input signal is passed outside the predetermined frequency range. Set to characteristics, The signal from the frequency conversion means is input Ru First 2 A band pass filter and the first power level of the signal output from the first band pass filter; 2 The signal difference means for outputting a difference from the power level of the signal output from the band pass filter, and the power level of the signal output from the signal difference means is compared with a predetermined threshold level, and from the predetermined threshold level. Comparison means for detecting the detection target signal as a predetermined tone signal when the detection target signal is high.
[0024]
Claim 2 The facsimile apparatus according to claim 1 includes the tone detection apparatus according to claim 1.
[0025]
Claim 3 The communication terminal device according to claim 1 includes the tone detection device according to claim 1.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
[0029]
First, FIG. 1 shows a block configuration of a facsimile apparatus 1 including a tone detection apparatus according to an embodiment of the present invention as a configuration.
[0030]
In FIG. 1, a facsimile apparatus 1 includes a system control unit 2, a ROM 3, a RAM 4, a scanner 5, a plotter 6, an image memory 7, an encoding / decoding unit 8, an operation display unit 9, a modem 10, a network control unit 11, and The system bus 12 is used.
[0031]
The system control unit 2 controls each unit of the apparatus while using the RAM 4 as a work area according to a control program written in the ROM 3.
[0032]
As described above, the ROM 3 is a read-only memory in which a control program and a data table for the system control unit 2 to control each unit of the apparatus are stored.
[0033]
The RAM 4 is a random access memory used as a work area for the system control unit 2 as described above. Note that the RAM 4 is backed up by a backup circuit (not shown), and the stored contents are retained even when the apparatus power is shut off.
[0034]
The scanner 5 is for obtaining image data by reading a document image at a predetermined reading line density such as 3.85 lines / mm, 7.7 lines / mm, and 15.4 lines / mm. The plotter 6 records and outputs the received image data according to the linear density, and records and outputs the image data read by the scanner 5 according to the linear density (copy operation).
[0035]
The image memory 7 temporarily stores the image data read by the scanner 5 as a file for transmission to the memory, or temporarily stores the received image data as a file until it is recorded by the plotter 6. belongs to.
[0036]
The encoding / decoding unit 8 encodes and compresses transmission image data with a predetermined encoding method such as an MH encoding method, an MR encoding method, or an MMR encoding method that is compatible with G3 facsimile, while receiving image data. Is decoded and expanded by a predetermined decoding method corresponding to the MH encoding method, the MR encoding method, the MMR encoding method, or the like.
[0037]
The operation display unit 9 is provided with a numeric keypad for designating a destination facsimile number, a transmission start key, a one-touch dial key, a function key, and various other keys, and a display such as a liquid crystal display device. It displays the operating state of the device to be notified to the user and various messages.
[0038]
The modem 10 is a G3 facsimile modem that modulates data transmitted to the line via the network control unit 11 and demodulates a signal received from the line via the network control unit 11. The modem 10 transmits a DTMF signal corresponding to the dial number and detects various tone signals such as a dial tone, a ringing tone, and a busy tone coming from the line by the tone detector 10a.
[0039]
The network control unit 11 is connected to a line and performs connection control with a line such as closing / release of a DC loop of the line, detection of polarity reversal of the line, detection of line release, and generation of a dial pulse. It is. The system bus 12 is a signal line for the above units to exchange data.
[0040]
The facsimile apparatus 1 configured as described above performs facsimile transmission / reception processing shown in FIGS.
[0041]
First, in FIG. 2, the system control unit 2 monitors whether an incoming call is detected by the network control unit 11 or whether a document is detected by a document sensor (not shown) of the scanner 5. (No in decision 101, no loop in decision 102).
[0042]
When there is an incoming call (Yes in decision 101), the network control unit 11 is controlled to close the line (off-hook) (process 103), thereby establishing a line with the transmission source device and the G3 facsimile. The facsimile reception process based on the protocol is performed while monitoring whether a busy tone (busy sound) signal is detected by the tone detection unit 10a (process 104, No in decision 105, No loop in decision 106).
[0043]
When the facsimile reception process is completed (Yes in decision 106), the line is opened (off hook) and the facsimile reception is terminated (process 107), but the busy tone coming from the line (subscriber exchange) during the facsimile reception process. When a signal is detected, that is, when the transmission source is off-hooked for some reason during the facsimile transmission process and the line is disconnected (Yes in decision 105), the line is released (off-hook) to receive the facsimile. Cancel (process 107).
[0044]
When the document is set in the determination 102 (Yes in the determination 102), the process waits until the transmission destination is input (No loop in the determination 108), and the transmission destination is displayed on the operation display unit 9 by the one-touch dial, speed dial, or When input is made by manual dialing (Yes at decision 108), the process waits until the start key for instructing transmission is pressed (No loop at decision 109). When the start key is pressed (Yes at decision 109), the line The tone detector 10a detects a busy tone signal coming from (subscriber exchange) or monitors whether there is a response from the other party (inversion of line polarity) (No in decision 111, No loop in decision 112) ).
[0045]
When the other party is communicating or talking, and the tone detector 10a detects a busy tone, the line is released (off hook) and facsimile transmission is stopped (step 116). When a response from the other party is detected (Yes in decision 112), facsimile transmission processing based on the G3 facsimile protocol is performed while monitoring whether a busy tone (busy tone) signal is detected by the tone detection unit 10a. (Process 113, No of decision 114, No loop of decision 115).
[0046]
When the facsimile transmission process is completed (Yes in decision 115), the line is released (off hook) and the facsimile transmission is terminated (process 116), but the busy tone coming from the line (subscriber exchange) during the facsimile transmission process. When the signal is detected, that is, when the other party is off-hooked during the facsimile reception process for some reason and the line is disconnected (Yes in decision 114), the line is released (off-hook) and the facsimile transmission is performed. Cancel (process 116).
[0047]
As described above, when a busy tone signal is detected during facsimile transmission / reception, it is necessary to prevent the occupation of an unnecessary line by opening the line, but a communication signal that is not a busy tone signal coming from the line is used as a busy tone signal. If it is erroneously detected, normal communication cannot be performed, so it is necessary to accurately detect the busy tone signal.
[0048]
Also, facsimile transmission is started after confirming the dial tone signal coming from the line (subscriber exchange) at the time of outgoing call, or the ring tone signal coming from line (subscriber exchange) at the time of outgoing call is checked. In such a case, it is necessary to accurately detect the dial tone signal and the ring tone signal.
[0049]
In Japan, tone signals such as busy tone signals, dial tone signals, and ring tone signals coming from the subscriber exchange on the line are basically 400 ± 19 Hz signals, and the dial tone signals are 400 ± 19 Hz. The continuous transmission, the ringing tone signal and the busy tone are signals which are intermittently transmitted at 400 ± 19 Hz with a predetermined intermittent characteristic. Therefore, various tone signals can be detected by detecting a signal of 400 ± 19 Hz coming from a subscriber exchange (or an extension exchange when the facsimile apparatus 1 is connected to an extension). The detected signal of 400 ± 19Hz is sent out The This can be easily done by measuring the lengths of the periods that are present and the periods that are not transmitted.
[0050]
Before describing the tone detector according to the present invention, a conventional tone detector will be described with reference to FIG. 4 for comparison.
[0051]
In the figure, the tone detection unit 10 a inputs a signal from the line as a detection target signal, and the input signal is input to the band pass filter 20.
[0052]
The band pass filter 20 has the characteristics shown in FIG. 5, and the center frequency f0 should ideally be set to the frequency of the tone signal coming from the line. The pass band of the band pass filter 20 is f0−Δfc to f0 + Δfc. When a tone signal arriving from the line is input to the band pass filter 20 as an input signal, the frequency of the tone signal as the input signal is As shown in FIG. 6 (a), if it is within the range of the center frequency f0 ± Δfc, it passes through the band-pass filter 20 and is input to the power integrator 22 with almost no attenuation. On the other hand, if the frequency of the tone signal input to the band pass filter 20 is outside the range of the center frequency f0 ± Δfc, as shown in FIG. Input to the integrator 22.
[0053]
If the pass band width ± Δfc of the band-pass filter 20 is too wide, the communication signal is erroneously detected as a tone signal, so the frequency of the tone signal should be widened to cover the variation of each destination. Can not be done, it must be narrowed to some extent.
[0054]
The bandpass filter 20 has the configuration shown in FIG. 7, and an input signal is input to the multiplier M1, multiplied by the filter coefficient K1, the output of the multiplier M1 is input to the adder A1, and the adder A1 is also input. The outputs of the multipliers M3 and M4 are also input. The output from the adder A1 is input to the multiplier M2. The Then, the value 2 is multiplied by a fixed constant T1, and the output of the multiplier M2 is input to the multiplier M5 and also input to the delay line D1, and the output of the delay line D1 is input to the multiplier M3. At the same time, it is input to the delay line D2. The multiplier M3 multiplies the output of the delay line D1 and the filter coefficient K2. Closed The result is input as an output to adder A1. The output of the delay line D2 is input to the multiplier M4. In the multiplier M4, the result of multiplying the output of the delay line D2 and the filter coefficient K3 is input as an output to the adder A1.
[0055]
In the multiplier M5, the output of the multiplier M2 is multiplied by the filter coefficient K4, the output of the multiplier M5 is input to the adder A2, and the output of each of the multipliers M7 and M8 is input to the adder A2. Is also entered. Output from adder A2 is input to multiplier M6 The Then, the value 2 is multiplied by a fixed constant T2, and the output of the multiplier M6 becomes the output of the bandpass filter 20, and is input to the delay line D3, and the output of the delay line D3 is input to the multiplier M7. And input to the delay line D4. In the multiplier M7, the result of multiplying the output of the delay line D3 and the filter coefficient K5 is input to the adder A1 as an output. The output of the delay line D4 is input to the multiplier M8. In the multiplier M8, the result of multiplying the output of the delay line D4 and the filter coefficient K6 is input to the adder A2 as an output.
[0056]
Various characteristics such as the center frequency, the pass band width, and the cutoff characteristic of the band pass filter 20 configured as described above are set by setting values set as the filter coefficients K1 to K6. For this purpose, the conventional tone detection unit 10a of FIG. 4 sets the filter coefficient group by making it possible to rewrite the stored contents of the filter coefficient storage unit 21 storing the filter coefficients K1 to K6 from the outside. The characteristics of the pass filter 20 were set.
[0057]
However, in this case, the system control unit 2 must store a group of filter coefficients corresponding to slightly different characteristics as a table in the ROM 3 and the RAM 4 in order to cope with fluctuations in the frequency of the tone signal for each destination. In other words, a large amount of storage capacity is consumed.
[0058]
In FIG. 4, the signal that has passed through the band-pass filter 20 is input to the power integrator 22, and the signal power is calculated.
[0059]
FIG. 8 shows the configuration of the power integrator 22. In the figure, the output (real part) from the band pass filter 20 is input to a multiplier M10, squared and output. The output (imaginary part) from the band pass filter 20 is input to the multiplier M11 and squared and output.
[0060]
The outputs from the multipliers M10 and M11 are input to the adder A10, added, input to the multiplier M12, multiplied by the power integration coefficient K10, and input to the adder A11. The output from the multiplier M12 and the output from the multiplier M13 are input to the adder A11, added and output. The output from the adder A11 becomes the output of the power integrator 22, and is also input to the delay line D10. The output from the delay line D10 is input to the multiplier M13 and is multiplied by the power integration coefficient K11, and is added to the adder A11. Is input.
[0061]
In FIG. 4, the output from the power integrator 22 is input to the comparator 23 and compared with a threshold value arbitrarily set from the outside stored in the threshold value storage unit 24. Is too large, the input signal is determined as a tone signal, and when it is small, the input signal is not determined as a tone signal. The system control unit 2 can determine the presence / absence of the tone signal and the type of the tone signal by measuring the period in which the tone detection unit 10a determines the input signal as the tone signal and the period in which the input signal is not determined.
[0062]
Note that the threshold value set in the threshold value storage unit 24 corresponds to the comparison threshold level shown in FIGS. 5, 6A, and 6B, and in FIG. Since the frequency of the tone signal is within the pass band of the band pass filter 20, the output of the power integrator 22 exceeds the comparison threshold level. However, in FIG. Because it is outside the passband of the filter 20, the output of the power integrator 22 does not exceed the comparison threshold level.
[0063]
In the conventional tone detection unit 10a shown in FIG. 4 configured as described above, it is necessary to calculate, verify, and store a large number of filter coefficient groups that can be set in the filter coefficient storage unit 21 in accordance with the destination. However, what is different for each destination is the frequency of the tone signal, and there is no need to change the pass bandwidth and the cutoff characteristic according to the destination.
[0064]
However, even if only the center frequency f0 is changed by fixing the passband width and cutoff characteristic of the bandpass filter 20, it is not possible to set only the center frequency f0 alone. As shown in FIG. K2 to K6 must be set as a set, and the memory capacity required for setting the characteristics of the band pass filter 20 for each destination cannot be reduced.
[0065]
Therefore, in the present invention, the tone detector 10a is configured as shown in FIG.
[0066]
In the configuration of the tone detector 10a shown in the figure, the difference from the tone detector 10a of the conventional configuration shown in FIG. 4 is that a filter coefficient group corresponding to the destination is first set in the filter coefficient storage unit 21. This is no longer necessary.
[0067]
That is, a fixed value is set for each of the filter coefficients K1 to K6 of the band pass filter 20, and the characteristic is set to the characteristic indicated by the solid line in FIG. Specifically, the characteristics are set such that the center frequency is DC (0 Hz) and the passband width is ± fc.
[0068]
Therefore, even if the detection target signal is directly input to the band pass filter 20, if it is a tone signal of several hundred Hz that comes from the line as the detection target signal, the tone signal is greatly attenuated as it is, It is not detected as a tone signal by the comparator 23.
[0069]
However, in the tone detection unit 10 a according to the present invention shown in FIG. 9, an input signal to be detected is input to the band pass filter 20 via the frequency converter 25.
[0070]
The frequency converter 25 receives the transmission output of the transmitter 26 that transmits at the frequency set in the frequency storage unit 27, shifts the input signal by the transmission frequency of the transmitter 26, and inputs the input signal to the band pass filter 20. In the frequency storage unit 27, the system control unit 2 sets a frequency.
[0071]
FIG. 11 shows the configuration and interrelationship of the frequency converter 25, the transmitter 26, and the frequency storage unit 27.
[0072]
In the figure, the frequency f set in the frequency storage unit 27 includes a sine wave generation unit (Sin (2πft)) of the transmitter 26 and a Cos wave generation unit (Cos (2πft) whose phase is 90 degrees shifted from the Sin wave. )), The oscillator 26 generates a sine wave and a Cos wave of frequency f. The sine wave is input to the multiplier M20 of the frequency converter 25, and the Cos wave is input to the multiplier M21. The
[0073]
In the frequency converter 25, the input signal is input to the multipliers M20 and M21, multiplied by the Sin wave and Cos wave in each multiplier, and the input signal conversion output (imaginary part) is output from the multiplier M20. The multiplier M21 outputs an input signal conversion output (real part).
[0074]
Now, it is assumed that the frequency of the tone signal as an input signal is fi and Sin (2πfit), the frequency set in the frequency storage unit 27 is f0, and the signal input to the multiplier M20 is Sin ( 2πf0t), and the signal input to the multiplier M21 is a signal multiplied by Cos (2πf0t).
The output of the multiplier M20 is

It becomes.
The output of the multiplier M21 is

It becomes.
[0075]
Therefore, in FIG. 9, the signal input from the frequency converter 25 to the bandpass filter 20a is shifted by −f0 from the signal obtained by shifting the frequency of the detection target signal input to the frequency converter 25 by + f0. The signal is synthesized.
[0076]
On the other hand, since the band pass filter 20a has the characteristic indicated by the solid line in FIG. 10, if the detection target signal input to the frequency converter 25 is within the tone detection range indicated by the alternate long and short dash line in FIG. The signal component shifted by + f0 by 25 is greatly attenuated because it falls outside the passband of the bandpass filter 20a shown by the solid line in FIG. 10, but the signal component shifted by -f0 by the frequency converter 25 is Since it falls within the pass band of the band pass filter 20a shown by the solid line in FIG. 10, it is output from the band pass filter 20a with almost no attenuation.
[0077]
That is, the center frequency of the virtual bandpass filter constituted by the frequency converter 25 and the bandpass filter 20a is the value of the filter coefficient group stored in the filter coefficient storage unit 21 that determines the characteristics of the bandpass filter 20a. Can be easily changed while fixing other characteristics such as a pass bandwidth other than the center frequency by simply setting the frequency shift amount in the frequency storage unit 27. The setting of the frequency shift amount to the frequency storage unit 27 is input by the system control unit 2 by a predetermined operation from the operation display unit 9 performed by a worker or a service person at the time of shipment of the device or at the time of installation of the device. This is done by writing the frequency shift amount in the frequency storage unit 27.
[0078]
Therefore, only by setting the frequency of the tone signal corresponding to the destination at the time of shipment of the device in the frequency storage unit 27, it becomes possible to cope with the difference in the frequency of the tone signal for each destination, and the filter of the band pass filter 20a. Compared to the case where a large number of coefficient groups are stored in advance and one of the filter coefficient groups is set according to the difference in the frequency of the tone signal for each destination, a large number of filter coefficient groups are stored. Can save memory.
[0079]
Next, a modification of the tone detector 10a according to the present invention shown in FIG. 9 is shown in FIG.
[0080]
In FIG. 12, the difference from the tone detector 10a shown in FIG. 9 is that, instead of the band pass filter 20a and the power integrator 22 between the frequency converter 25 and the comparator 23, a band pass filter 20b and a power integrator are provided. This is the point that the difference circuit 28 is disposed while the filter 22a, the band pass filter 20c and the power integrator 22b are disposed. The bandpass filters 22b and 20c are the same as the bandpass filter 20a, but the filter characteristics set by the filter coefficients stored in the filter count storage unit 21 are different. The power integrators 22 a and 22 b are the same as the power integrator 22.
[0081]
The detection target input signal frequency-converted by the frequency converter 25 is input to the band-pass filter 22b and the band-pass filter 22c. In the signal input to the band pass filter 22b, frequency components corresponding to the filter characteristics of the band pass filter 22b are blocked, and other frequency components are input to the power integrator 22a. The power integrator 22a The level of the signal input from 20 b is detected and input to the difference circuit 28. In the signal input to the band pass filter 22c, frequency components corresponding to the filter characteristics of the band pass filter 22c are blocked, and other frequency components are input to the power integrator 22b. The power integrator 22b The level of the signal input from 20 c is detected and input to the difference circuit 28.
[0082]
The difference circuit 28 inputs a difference level between the signal level input from the power integrator 22 a and the signal level input from the power integrator 22 b to the comparator 23. The comparator 23 compares the level input from the difference circuit 28 with the threshold value set in the threshold value storage 24. If the level is equal to or higher than the set threshold value, the input signal is a tone signal. Outputs the judgment result that there is.
[0083]
Here, a detection example in the tone detection unit 12a shown in FIG. 12 will be described. Assume that the tone signal to be detected is 1300 Hz ± 50 Hz. In this case, the input signal is a DTMF signal corresponding to “2” (combination of 697 Hz and 1336 Hz), corresponding to “5” (combination of 770 Hz and 1336 Hz), or “8 ”(Combination of 852 Hz and 1336 Hz), the detection by the conventional tone detector 10a as shown in FIG. 4 or the tone detector 10a shown in FIG. If the 1336 Hz component of the signal is detected at a threshold level or higher, it is detected that there is a tone signal, but since it is actually a DTMF signal, a false detection will occur. Therefore, when the DTMF signal is put on the line by pressing the bush button on the partner device side, the DTMF signal is erroneously detected as a 1300 Hz ± 50 Hz tone signal used for communication protocol exchange. This will interfere with communication operations.
[0084]
In order not to erroneously detect such a DTMF signal as a tone signal, even when a signal at 1336 Hz is detected as a signal within a range of 1300 Hz ± 50 Hz, signals at 697 Hz, 770 Hz, and 852 Hz are simultaneously detected. In this case, it is sufficient not to detect the tone signal.
[0085]
Therefore, in the tone detection unit 10a shown in FIG. 12, 1300 Hz is set as the frequency set in the frequency storage unit 27 and the input signal is shifted by 1300 Hz. Then, the filter coefficient for the band-pass filter 20b set in the filter coefficient storage unit 21 is the filter characteristic of the band-pass filter 20b, as shown in FIG. 13A, only the signal component in the frequency range of ± 50 Hz. Set the coefficient to pass. Further, the filter coefficient for the band pass filter 20c to be set in the filter coefficient storage unit 21 is a signal component having a frequency characteristic of ± 525 Hz ± 100 Hz as shown in FIG. Set the coefficient so that only passes.
[0086]
As a result, the +36 Hz signal obtained by shifting the 1336 Hz component of the frequency components of the input signal by 1300 Hz passes through the band-pass filter 20b as a signal within the range of ± 50 Hz, thereby causing the difference circuit 28 from the power integrator 22a. Even if there is a certain level of input to the “+” input, the components of 697 Hz, 770 Hz, or 852 Hz of the frequency components of the input signal are obtained by shifting by 1300 Hz, respectively, −603 Hz, −530 Hz, Alternatively, the -448 Hz signal passes through the bandpass filter 20 c as a signal within the range of ± 525 Hz ± 100 Hz, so that there is a constant level input from the power integrator 22 b to the “−” input of the difference circuit 28, The signal level output from the difference circuit 28 is almost zero, and the comparator 3 by the determined tone signal is eliminated.
[0087]
As a result, a DTMF signal including a signal in the frequency range of the tone signal to be detected is not erroneously detected as a tone signal.
[0088]
Next, another example of detection in the tone detector 10a shown in FIG. 12 will be described.
[0089]
In the tone detection unit 10a shown in FIG. 12, the center frequency of the tone signal to be detected is set as the frequency to be set in the frequency storage unit 27, and the input signal is shifted by the center frequency. Then, the filter coefficient for the band-pass filter 20b set in the filter coefficient storage unit 21 is the filter characteristic of the band-pass filter 20b, and only the signal component in the frequency range of ± fcHz as shown in FIG. Set the coefficient to pass. Further, the filter coefficient for the band pass filter 20c to be set in the filter coefficient storage unit 21 is such that the filter characteristic of the band pass filter 20c is only a signal component outside the frequency range of ± fcHz as shown in FIG. Set the coefficient to pass through.
[0090]
As a result, of the frequency components of the input signal, signals in the frequency range of ± fcHz shifted by the center frequency of the tone signal to be detected are passed through the bandpass filter 20b as signals within the range of ± fcHz. Even when there is a certain level of input from the power integrator 22a to the “+” input of the difference circuit 28 from the power integrator 22a, at the same time, the center frequency ± of the tone signal to be detected out of the frequency components of the input signal A signal obtained by shifting the component outside the range of fcHz by the center frequency passes through the band-pass filter 20c as a signal outside the range of ± fcHz, so that the power integrator 22b and the difference circuit 28 " Since the “−” input has a certain level of input, the signal level output from the difference circuit 28 is almost zero and is Signal determined to it is eliminated.
[0091]
As a result, a signal such as a DTMF signal including a signal in the frequency range of the tone signal to be detected is not erroneously detected as a tone signal. In addition, since the characteristics of the band pass filter 20c are simple characteristics that pass outside the frequency range of the tone signal to be detected, the filter coefficients of the band pass filters 20b and 20c can be reduced. Memory capacity can be saved.
[0092]
Further, for example, fc = ± 10 Hz, ± 50 Hz, ± 100 Hz, ± 150 Hz, ± 200 Hz, etc. can be selected as the detection frequency band fc, and the facsimile apparatus 1 sets a filter coefficient value for the tone detector 10a. Instead, the detection frequency bands prepared in advance as described above are set, and the tone detector 10a filters the bandpass filters 20b and 20c that generate the characteristics shown in FIG. 14 for each detection frequency band. The coefficient value for use may be selected and used. As a result, the main body of the facsimile apparatus 1 does not need to hold all the coefficient values, and a tone detection apparatus with few false detections can be realized without increasing the memory.
[0093]
In the embodiment described above, the tone detection apparatus according to the present invention is applied to a facsimile apparatus which is one of communication terminal apparatuses. However, the tone detection apparatus according to the present invention is not limited to this, and is connected via a line. The present invention can be similarly applied to other communication terminal devices that perform other data communication.
[0094]
【The invention's effect】
Claim 1 According to the invention, the signal to be detected includes a signal component having a certain level or higher in the frequency range of the tone signal to be detected, and at the same time, a signal component other than the signal component in the frequency range of the tone signal to be detected. If the signal is a signal that should not be detected as a tone signal such as a DTMF signal, the output of the signal difference means is almost 0 level and the detection target signal is not determined as a tone signal. Thus, there is an effect that a signal that includes a signal component in the frequency range of the tone signal to be detected but is not a tone signal is not erroneously detected as a tone signal.
In addition, the first band pass filter that passes the frequency range of the tone signal to be detected and the first band pass filter that passes outside the frequency range of the tone signal to be detected. 2 The cutoff frequency is the same as that of the band pass filter. Necessary The necessary filter coefficients can be reduced, the memory capacity for storing the filter coefficients can be reduced correspondingly, and the first and second filter coefficients can be reduced. 2 An effect is obtained in which the setting of the cutoff frequency of the bandpass filter can be changed relatively easily.
[0095]
Claim 2 According to the invention according to claim 1 The effect of the invention can be obtained in the facsimile apparatus.
[0096]
Claim 3 According to the invention according to claim 1 The effect that the effect of the invention which concerns can be acquired in a communication terminal device is acquired.
[Brief description of the drawings]
FIG. 1 is a diagram showing a block configuration of a facsimile apparatus including a tone detection apparatus according to an embodiment of the present invention as a configuration.
FIG. 2 is a flowchart showing a facsimile transmission / reception processing procedure in the facsimile apparatus according to the embodiment of the present invention.
FIG. 3 is a flowchart showing a facsimile transmission / reception processing procedure in the facsimile apparatus according to the embodiment of the present invention together with FIG. 2;
FIG. 4 is a diagram showing a configuration of a conventional tone detector compared with a tone detector according to the present invention.
5 is a diagram showing characteristics of a band pass filter of the tone detector shown in FIG. 4; FIG.
6 is a diagram showing the relationship between the characteristics of the band-pass filter of the tone detection unit shown in FIG. 4 and the frequency of the tone signal to be detected.
FIG. 7 is a diagram showing a configuration of a band pass filter.
FIG. 8 is a diagram showing a configuration of a power integrator.
FIG. 9 is a diagram showing a configuration of a tone detection unit according to the present invention.
10 is a diagram showing characteristics of a band pass filter of the tone detection unit shown in FIG.
11 is a diagram showing the configuration and relationship of a frequency converter, an oscillator, and a frequency storage unit in the tone detection unit shown in FIG.
12 is a diagram showing a modification of the tone detection unit shown in FIG. 9;
13 is a diagram illustrating a characteristic example of a band pass filter of the tone detection unit illustrated in FIG. 12;
14 is a diagram illustrating another characteristic example of the band-pass filter of the tone detection unit illustrated in FIG. 12. FIG.
[Explanation of symbols]
1 Facsimile device
2 System controller
3 ROM
4 RAM
5 Scanner
6 Plotter
7 Image memory
8 Coding / decoding unit
9 Operation display
10 Modem
10a Tone detector
11 Network control unit
12 System bus
20, 20a, 20b, 20c Band pass filter
21 Filter coefficient storage unit
22, 22a, 22b Power integrator
23 Comparator
24 threshold memory
25 Frequency converter
26 Oscillator
27 Frequency storage
T1, T2 filter constant
K1, K2, K3, K4, K5, K6, K10, K11 Filter coefficients
M1, M2, M3, M4, M5, M6, M10, M11, M12, M13, M20, M21 Multipliers
A1, A2, A10, A11, adder
D1, D2, D3, D4, D10 Delay line

Claims (3)

In a tone detection apparatus for detecting whether a detection target signal coming from a line is a tone signal in a predetermined frequency range,
A frequency conversion means for shifting the frequency of the detection target signal by a set frequency shift amount;
Shift amount setting means for setting the frequency shift amount;
The setting of the filter coefficient group is set to a characteristic to pass the predetermined frequency range of the frequency components of the input signal, a first band-pass filter signal from said frequency converting means are entered,
The setting of the filter coefficient group is set to a characteristic to pass the predetermined frequency range of the frequency components of the input signal, a second band-pass filter signal from said frequency converting means are entered,
Signal difference means for outputting a difference between the power level of the signal output from the first bandpass filter and the power level of the signal output from the second bandpass filter;
Comparing means for comparing the power level of the signal output from the signal difference means with a predetermined threshold level and detecting the detection target signal as a predetermined tone signal when the signal level is higher than the predetermined threshold level. A tone detection apparatus characterized by the above. A facsimile apparatus comprising the tone detection apparatus according to claim 1 . A communication terminal apparatus comprising the tone detection apparatus according to claim 1 .

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