MT3270BE1 [ZARLINK]
Wide Dynamic Range DTMF Receiver; 宽动态范围的DTMF接收器型号: | MT3270BE1 |
厂家: | ZARLINK SEMICONDUCTOR INC |
描述: | Wide Dynamic Range DTMF Receiver |
文件: | 总15页 (文件大小:488K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
MT3170B/71B, MT3270B/71B, MT3370B/71B
Wide Dynamic Range DTMF Receiver
Data Sheet
August 2005
Features
•
•
Wide dynamic range (50 dB) DTMF Receiver
Call progress (CP) detection via cadence
indication
Ordering Information
MT3170/71BE
MT3270/71BE
MT3370/71BS
MT3370/71BN
MT3370/71BSR
MT3371BNR
8 Pin PDIP
Tubes
8 Pin PDIP
Tubes
18 Pin SOIC
20 Pin SSOP
18 Pin SOIC
20 Pin SSOP
8 Pin PDIP*
8 Pin PDIP*
8 Pin PDIP**
20 Pin SSOP*
18 Pin SOIC*
18 Pin SOIC*
Tubes
•
•
•
•
•
4-bit synchronous serial data output
Tubes
Tape & Reel
Tape & Reel
Tubes
Software controlled guard time for MT3x70B
Internal guard time circuitry for MT3x71B
Powerdown option (MT317xB & MT337xB)
4.194304 MHz crystal or ceramic resonator
(MT337xB and MT327xB)
MT3270/71BE1
MT3171BE1
Tubes
MT3170BE1
Tubes
MT3370/BN1
MT3370/71BS1
MT3370/71BSR1
Tubes
Tubes
Tape & Reel
*Pb Free Matte Tin
**Pb Free Tin/Silver/Copper
•
•
External clock input (MT317xB)
Guarantees non-detection of spurious tones
-40°C to 85°C
Applications
•
•
•
Integrated telephone answering machine
End-to-end signalling
Fax Machines
➀
PWDN
Steering
Circuit
Digital
Guard
ESt
or
DStD
VDD
Voltage
➂
Time
Bias Circuit
VSS
High
Group
Filter
Parallel to
Serial
Converter
& Latch
ACK
Dial
Tone
Filter
Anti-
alias
Filter
Code
Converter
and
Digital
INPUT
AGC
Detector
Algorithm
Latch
Low
Group
Filter
Mux
SD
➁
Oscillator
OSC2
and
Clock
Circuit
Energy
Detection
OSC1
(CLK)
To All Chip Clocks
➀ MT3170B/71B and MT337xB only.
➁ MT3270B/71B and MT337xB only.
➂
MT3x71B only.
Figure 1 - Functional Block Diagram
1
Zarlink Semiconductor Inc.
Zarlink, ZL and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc.
Copyright 1995-2005, Zarlink Semiconductor Inc. All Rights Reserved.
MT3170B/71B, MT3270B/71B, MT3370B/71B
Data Sheet
Description
The MT3x7xB is a family of high performance DTMF receivers which decode all 16 tone pairs into a 4-bit binary
code. These devices incorporate an AGC for wide dynamic range and are suitable for end-to-end signalling. The
MT3x70B provides an early steering (ESt) logic output to indicate the detection of a DTMF signal and requires
external software guard time to validate the DTMF digit. The MT3x71B, with preset internal guard times, uses a
delay steering (DStD) logic output to indicate the detection of a valid DTMF digit. The 4-bit DTMF binary digit can be
clocked out synchronously at the serial data (SD) output. The SD pin is multiplexed with call progress detector
output. In the presence of supervisory tones, the call progress detector circuit indicates the cadence (i.e., envelope)
of the tone burst. The cadence information can then be processed by an external microcontroller to identify specific
call progress signals. The MT327xB and MT337xB can be used with a crystal or a ceramic resonator without
additional components. A power-down option is provided for the MT317xB and MT337xB.
MT3370B/71B
MT3170B/71B
MT3270B/71B
MT3370B/71B
20
19
18
17
16
15
14
13
12
11
1
2
NC
NC
NC
18
17
16
15
14
13
12
11
10
1
2
3
4
5
6
7
8
9
NC
INPUT
PWDN
OSC2
NC
VDD
NC
NC
INPUT
PWDN
CLK
VDD INPUT
VDD
1
2
3
4
8
7
6
5
1
2
3
4
8
7
6
5
INPUT
PWDN
NC
3
4
5
VDD
NC
NC
ESt/
ESt/
OSC2
DStD
ESt/DStD
NC
ESt/DStD
NC
DStD
6
7
OSC2
OSC1
VSS
OSC1
ACK
ACK
OSC1
NC
ACK
NC
ACK
SD
8
VSS
VSS
SD
SD
NC
SD
9
NC
NC
VSS
NC
NC
10
NC
8 PIN PLASTIC DIP
18 PIN PLASTIC SOIC
20 PIN SSOP
Figure 2 - Pin Connections
Pin Description
Pin #
327xB
Name
Description
337xB
317xB
2
4
6
1
2
3
1
-
3
INPUT DTMF/CP Input. Input signal must be AC coupled via capacitor.
OSC2 Oscillator Output.
OSC1 Oscillator/Clock Input. This pin can either be driven by:
(CLK) 1) an external digital clock with defined input logic levels. OSC2
should be left open.
2) connecting a crystal or ceramic resonator between OSC1 and
OSC2 pins.
9
11
4
5
4
5
VSS
SD
Ground. (0V)
Serial Data/Call Progress Output. This pin serves the dual function
of being the serial data output when clock pulses are applied after
validation of DTMF signal, and also indicates the cadence of call
progress input. As DTMF signal lies in the same frequency band as
call progress signal, this pin may toggle for DTMF input. The SD pin
is at logic low in powerdown state.
13
6
6
ACK
Acknowledge Pulse Input. After ESt or DStD is high, applying a
sequence of four pulses on this pin will then shift out four bits on the
SD pin, representing the decoded DTMF digit. The rising edge of the
first clock is used to latch the 4-bit data prior to shifting. This pin is
pulled down internally. The idle state of the ACK signal should be
low.
2
Zarlink Semiconductor Inc.
MT3170B/71B, MT3270B/71B, MT3370B/71B
Data Sheet
Pin Description
Pin #
Name
Description
337xB
327xB
317xB
15
7
7
ESt
(MT3x70B)
Early Steering Output. A logic high on ESt indicates that a DTMF
signal is present. ESt is at logic low in powerdown state.
Delayed Steering Output. A logic high on DStD indicates that a
valid DTMF digit has been detected. DStD is at logic low in
powerdown state.
DStD
(MT3x71B)
18
8
-
8
-
VDD
NC
Positive Power Supply (5 V Typ.) Performance of the device can
be optimized by minimizing noise on the supply rails. Decoupling
capacitors across VDD and VSS are therefore recommended.
1,5,7,8,
10, 12,
14,16,
17
No Connection. Pin is unconnected internally.
3
-
2
PWDN Power Down Input. A logic high on this pin will power down the
device to reduce power consumption. This pin is pulled down
internally and can be left open if not used. ACK pin should be at logic
’0’ to power down device.
Summary of MT3x70/71B Product Family
Device
Type
2 Pin
OSC
Ext
8 Pin
18 Pin
20 Pin
PWDN
ESt
DStD
CLK
MT3170B
MT3171B
MT3270B
MT3271B
MT3370B
MT3371B
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
√
Functional Description
The MT3x7xBs are high performance and low power consumption DTMF receivers. These devices provide wide
dynamic range DTMF detection and a serial decoded data output. These devices also incorporate an energy
detection circuit. An input voiceband signal is applied to the devices via a series decoupling capacitor. Following the
unity gain buffering, the signal enters the AGC circuit followed by an anti-aliasing filter. The bandlimited output is
routed to a dial tone filter stage and to the input of the energy detection circuit. A bandsplit filter is then used to
separate the input DTMF signal into high and low group tones. The high group and low group tones are then
verified and decoded by the internal frequency counting and DTMF detection circuitry. Following the detection
stage, the valid DTMF digit is translated to a 4-bit binary code (via an internal look-up ROM). Data bits can then be
shifted out serially by applying external clock pulses.
Automatic Gain Control (AGC) Circuit
As the device operates on a single power supply, the input signal is biased internally at approximately VDD/2. With
large input signal amplitude (between 0 and approximately -30 dBm for each tone of the composite signal), the
3
Zarlink Semiconductor Inc.
MT3170B/71B, MT3270B/71B, MT3370B/71B
Data Sheet
AGC is activated to prevent the input signal from being clipped. At low input level, the AGC remains inactive and the
input signal is passed directly to the hardware DTMF detection algorithm and to the energy detection circuit.
Filter and Decoder Section
The signal entering the DTMF detection circuitry is filtered by a notch filter at 350 and 440 Hz for dial tone rejection.
The composite dual-tone signal is further split into its individual high and low frequency components by two 6th
order switched capacitor bandpass filters. The high group and low group tones are then smoothed by separate
output filters and squared by high gain limiting comparators. The resulting squarewave signals are applied to a
digital detection circuit where an averaging algorithm is employed to determine the valid DTMF signal. For
MT3x70B, upon recognition of a valid frequency from each tone group, the early steering (ESt) output will go high,
indicating that a DTMF tone has been detected. Any subsequent loss of DTMF signal condition will cause the ESt
pin to go low. For MT3x71B, an internal delayed steering counter validates the early steering signal after a
predetermined guard time which requires no external components. The delayed steering (DStD) will go high only
when the validation period has elapsed. Once the DStD output is high, the subsequent loss of early steering signal
due to DTMF signal dropout will activate the internal counter for a validation of tone absent guard time. The DStD
output will go low only after this validation period.
Energy Detection
The output signal from the AGC circuit is also applied to the energy detection circuit. The detection circuit consists
of a threshold comparator and an active integrator. When the signal level is above the threshold of the internal
comparator (-35dBm), the energy detector produces an energy present indication on the SD output. The integrator
ensures the SD output will remain at high even though the input signal is changing. When the input signal is
removed, the SD output will go low following the integrator decay time. Short decay time enables the signal
envelope (or cadence) to be generated at the SD output. An external microcontroller can monitor this output for
specific call progress signals. Since presence of speech and DTMF signals (above the threshold limit) can cause
the SD output to toggle, both ESt (DStD) and SD outputs should be monitored to ensure correct signal identification.
As the energy detector is multiplexed with the digital serial data output at the SD pin, the detector output is selected
at all times except during the time between the rising edge of the first pulse and the falling edge of the fourth pulse
applied at the ACK pin.
Serial Data (SD) Output
When a valid DTMF signal burst is present, ESt or DStD will go high. The application of four clock pulses on the
ACK pin will provide a 4-bit serial binary code representing the decoded DTMF digit on the SD pin output. The rising
edge of the first pulse applied on the ACK pin latches and shifts the least significant bit of the decoded digit on the
SD pin. The next three pulses on ACK pin will shift the remaining latched bits in a serial format (see Figure 5). If less
than four pulses are applied to the ACK pin, new data cannot be latched even though ESt/DStD can be valid. Clock
pulses should be applied to clock out any remaining data bits to resume normal operation. Any transitions in excess
of four pulses will be ignored until the next rising edge of the ESt/DStD. ACK should idle at logic low. The 4-bit
binary representing all 16 standard DTMF digits are shown in Table 1.
FLOW
697
697
697
770
770
770
852
FHIGH
1209
1336
1477
1209
1336
1477
1209
DIGIT
b3
0
0
0
0
0
0
0
b2
0
0
0
1
1
1
1
b1
0
1
1
0
0
1
1
b0
1
0
1
0
1
0
1
1
2
3
4
5
6
7
4
Zarlink Semiconductor Inc.
MT3170B/71B, MT3270B/71B, MT3370B/71B
Data Sheet
FLOW
852
852
941
941
941
697
770
852
941
FHIGH
1336
1477
1336
1209
1477
1633
1633
1633
1633
DIGIT
8
b3
1
1
1
1
1
1
1
1
0
b2
0
0
0
0
1
1
1
1
0
b1
0
0
1
1
0
0
1
1
0
b0
0
1
0
1
0
1
0
1
0
9
0
*
#
A
B
C
D
Tab0le= L1O-GSICerLiOaWl D, 1e=cLoOdGeICBHitIGTHable
Note: b0=LSB of decoded DTMF digit and shifted out first.
Powerdown Mode (MT317xB/337xB)
The MT317xB/337xB devices offer a powerdown function to preserve power consumption when the device is not in
use. A logic high can be applied at the PWDN pin to place the device in powerdown mode. The ACK pin should be
kept at logic low to avoid undefined ESt/DStD and SD outputs (see Table 2).
MT317xB/337xB
ACK (input)
PWDN (input)
ESt/DStD (output)
SD (output)
status
low
low
Refer to Fig. 4 for
timing waveforms
Refer to Fig. 4 for
timing waveforms
normal operation
low
high
high
high+
low
high
low
low
undefined
low
undefined
undefined
powerdown mode
undefined
undefined
Table 2 - Powerdown Mode
+ =enters powerdown mode on the rising edge.
Frequency 1 (Hz)
Frequency 2 (Hz)
On/Off
Description
350
425
400
480
440
480
440
480
440
---
---
620
---
620
480
620
continuous
continuous
continuous
0.5s/0.5s
0.5s/0.5s
0.25s/0.25s
2.0s/4.0s
North American Dial Tones
European Dial Tones
Far East Dial Tones
North American Line Busy
Japanese Line Busy
North American Reorder Tones
North American Audible Ringing
North American Reorder Tones
0.25s/0.25s
Table 3 - Call Progress Tones
5
Zarlink Semiconductor Inc.
MT3170B/71B, MT3270B/71B, MT3370B/71B
Data Sheet
Parameter
Unit
Resonator
Crystal
R1
L1
C1
C0
Qm
∆f
Ohms
mH
pF
pF
-
6.580
0.359
4.441
34.890
150
95.355
15.1E-03
12.0
1.299E+03 101.2E+ 03
%
±0.2% ±0.01%
Table 4 - Recommended Resonator and Crystal Specifications
Note:
Qm=quality factor of RLC model, i.e., 1/2P¶R1C1.
L1
C1
C0
R1
R1 = Equivalent resistor.
L1 = Equivalent inductance.
C1 = Equivalent compliance.
C0 = Capacitance between electrode.
Resonator and Crystal Electric Equivalent Circuit
Oscillator
The MT327xB/337xB can be used in both external clock or two pin oscillator mode. In two pin oscillator mode, the
oscillator circuit is completed by connecting either a 4.194304 MHz crystal or ceramic resonator across OSC1 and
OSC2 pins. Specifications of the ceramic resonator and crystal are tabulated in Table 4. It is also possible to
configure a number of these devices employing only a single oscillator crystal. The OSC2 output of the first device
in the chain is connected to the OSC1 input of the next device. Subsequent devices are connected similarly. The
oscillator circuit can also be driven by an 4.194304 MHz external clock applied on pin OSC 1. The OSC2 pin should
be left open.
For MT317xB devices, the CLK input is driven directly by an 4.194304 MHz external digital clock.
Applications
The circuit shown in Figure 3 illustrates the use of a MT327xB in a typical receiver application. It requires only a
coupling capacitor (C1) and a crystal or ceramic resonator (X1) to complete the circuit.
The MT3x70B is designed for user who wishes to tailor the guard time for specific applications. When a DTMF
signal is present, the ESt pin will go high. An external microcontroller monitors ESt in real time for a period of time
set by the user. A guard time algorithm must be implemented such that DTMF signals not meeting the timing
requirements are rejected. The MT3x71B uses an internal counter to provide a preset DTMF validation period. It
requires no external components. The DStD output high indicates that a valid DTMF digit has been detected.
The 4.194304 MHz frequency has a secondary advantage in some applications where a real time clock is required.
A 22-bit counter will count 4,194,304 cycles to provide a one second time base.
6
Zarlink Semiconductor Inc.
MT3170B/71B, MT3270B/71B, MT3370B/71B
Data Sheet
VDD
C1
8
1
VDD
DTMF/CP Input
INPUT
MT327xB
7
6
5
2
3
OSC2
OSC1
ESt/DStD
ACK
X1
To microprocessor or
microcontroller
4
VSS
SD
COMPONENTS LIST:
C1 = 0.1 µF ± 10 %
X1 = Crystal or Resonator (4.194304 MHz)
Figure 3 - Application Circuit for MT327xB
7
Zarlink Semiconductor Inc.
MT3170B/71B, MT3270B/71B, MT3370B/71B
Data Sheet
Absolute Maximum Ratings† - Voltages are with respect to VSS=0V unless otherwise stated.
Parameter
DC Power Supply Voltage
Symbol
Min.
Max.
Units
1
2
3
4
5
V
DD-VSS
VI/O
II/O
6
V
V
Voltage on any pin (other than supply)
Current at any pin (other than supply)
Storage temperature
-0.3
-65
6.3
10
mA
°C
TS
150
500
Package power dissipation
† Exceeding these values may cause permanent damage. Functional operation under these conditions is not implied.
PD
mW
Recommended Operating Conditions - Voltages are with respect to VSS=0V unless otherwise stated
Parameter
Sym.
Min.
Typ.‡
Max. Units
Test Conditions
1
2
3
4
Positive Power Supply
VDD
fOSC
∆fOSC
Td
4.75
5.0
5.25
V
MHz
%
Oscillator Clock Frequency
Oscillator Frequency Tolerance
Operating Temperature
4.194304
±0.1
85
-40
25
°C
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
DC Electrical Characteristics - Voltages are with respect to VDD=5V±5%,VSS=0V, and temperature -40 to 85°C, unless otherwise
stated.
Characteristics
Sym.
Min.
Typ.‡
Max.
Units
Test Conditions
1
2
Operating supply current
Standby supply current
IDD
3
8
mA
IDDQ
30
100
µA
PWDN=5V, ACK=0V
ESt/DStD = SD = 0V
3a
3b
Input logic 1
VIH
VIH
4.0
3.5
V
V
Input logic 1
MT327xB/MT337xB
MT327xB/MT337xB
(for OSC1 input only)
4a
4b
Input logic 0
VIL
VIL
1.0
1.5
V
V
Input logic 0
(for OSC1 input only)
5
6
Input impedance (pin 1)
RIN
IPD
50
kW
mA
Pull-down Current
(PWDN, ACK pins)
25
with internal pull-down
resistor of approx. 200 kΩ.
PWDN/ACK = 5V
7
8
Output high (source)
current
IOH
IOL
0.4
1.0
4.0
9.0
mA
mA
VOUT=VDD-0.4V
Output low (sink) current
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing.
VOUT=VSS+0.4V
8
Zarlink Semiconductor Inc.
MT3170B/71B, MT3270B/71B, MT3370B/71B
Data Sheet
AC Electrical Characteristics - voltages are with respect to VDD=5V±5%, VSS=0V and temperature -40 to +85°C unless otherwise
stated.
Characteristics
Sym.
Min.
Typ.‡
Max.
Units
Test Conditions*
1
Valid input signal level
-50
0
dBm
1,2,3,5,6,12
(each tone of composite signal)
2.45
775
mVRMS
2
3
4
5
6
7
8
9
Positive twist accept
Negative twist accept
Frequency deviation accept
Frequency deviation reject
Third tone tolerance
Noise tolerance
8
8
dB
dB
1,2,3,4,11,12,15
1,2,3,4,11,12,15
1,2,3,5,12
1,2,3,5,12,15
1,2,3,4,5,12
7,9,12
±1.5%± 2Hz
±3.5%
-16
-12
+15
dB
dB
Dial tone tolerance
dB
8,10,12
Supervisory tones detect level
(Total power)
-35
3
dBm
16
10 Supervisory tones reject level
11 Energy detector attack time
12 Energy detector decay time
-50
6.5
25
dBm
ms
16
16
16
tSA
tSD
1.0
ms
13a Powerdown time
13b Powerup time
10
30
50
ms
ms
ms
IDDQ ≤ 100µA
MT3170B/3370B
MT3171B/3371B
Note 14
14 Tone present detect time (ESt
logic output)
tDP
tDA
tREC
tREC
3
13
3
20
15
40
ms
ms
ms
ms
MT3x70B
MT3x70B
MT3x71B
MT3x71B
15 Tone absent detect time (ESt
logic output)
16 Tone duration accept
(DStD logic output)
17 Tone duration reject
(DStD logic output)
20
9
Zarlink Semiconductor Inc.
MT3170B/71B, MT3270B/71B, MT3370B/71B
Data Sheet
AC Electrical Characteristics - voltages are with respect to VDD=5V±5%, VSS=0V and temperature -40 to +85°C unless otherwise
stated.
Characteristics
Sym.
Min.
Typ.‡
Max.
Units
Test Conditions*
18 Interdigit pause accept (DStD
logic output)
tID
40
ms
MT3x71B
19 Interdigit pause reject (DStD
logic output)
tDO
20
ms
MT3x71B
20 Data shift rate 40-60% duty cycle fACK
1.0
3.0
MHz
ns
13,15
21 Propagation delay
(ACK to Data Bit)
tPAD
100
140
1MHz fACK
13,15
,
22 Data hold time (ACK to SD)
tDH
30
50
ns
13,15
‡ Typical figures are at 25°C and are for design aid only: not guaranteed and not subject to production testing
* Test Conditions
1. dBm refers to a reference power of 1 mW delivered into a 600 ohms load.
2. Data sequence consists of all DTMF digits.
3. Tone on = 40 ms, tone off = 40 ms.
4. Signal condition consists of nominal DTMF frequencies.
5. Both tones in composite signal have an equal amplitude.
6. Tone pair is deviated by ±1.5%± 2 Hz.
7. Bandwidth limited (0-3 kHz) Gaussian noise.
8. Precise dial tone frequencies are 350 Hz and 440 Hz (± 2%).
9. Referenced to lowest level frequency component in DTMF signal.
10. Referenced to the minimum valid accept level.
11. Both tones must be within valid input signal range.
12. External guard time for MT3x70B = 20 ms.
13. Timing parameters are measured with 70pF load at SD output.
14. Time duration between PWDN pin changes from ‘1‘ to ‘0‘ and ESt/DStD becomes active.
15. Guaranteed by design and characterization. Not subject to production testing.
16. Value measured with an applied tone of 450 Hz.
10
Zarlink Semiconductor Inc.
MT3170B/71B, MT3270B/71B, MT3370B/71B
Data Sheet
tDO
tREC
DTMF
DTMF
Tone #n
DTMF
Input
Signal
Tone
INPUT
Tone #n + 1
#n + 1
tDA
tDP
ESt
(MT3x70B)
tID
tREC
DStD
(MT3x71B)
ACK
SD
tSA
tSD
LSB
LSB
MSB
MSB
Input
Signal
Envelope
b0b1b2b3
b0b1b2b3
tDO
tID
- maximum allowable dropout during valid DTMF signals. (MT3x7xB).
- minimum time between valid DTMF signals (MT3x71B).
tREC
tREC
tDA
tDP
- maximum DTMF signal duration not detected as valid (MT3x7xB).
- minimum DTMF signal duration required for valid recognition (MT3x71B).
- time to detect the absence of valid DTMF signals (MT3x70B).
- time to detect the presence of valid DTMF signals (MT3x70B).
- supervisory tone integrator attack time (MT3x7xB).
tSA
tSD
- supervisory tone integrator decay time (MT3x7xB).
Figure 4 - Timing Diagram
ESt/DStD
1/fACK
VIH
ACK
VIL
tPAD
tDH
VIH
DTMF Energy
Detect
DTMF Energy
Detect
SD
b0
LSB
b1
b2
b3
MSB
VIL
Figure 5 - ACK to SD Timing
11
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