Philips UBA1702T-C1, UBA1702AT-C1, UBA1702A-C1 Datasheet

DATA SH EET
Product specification Supersedes data of 1996 Jan 09 File under Integrated Circuits, IC03
1997 Sep 29
INTEGRATED CIRCUITS
UBA1702; UBA1702A
1997 Sep 29 2
Philips Semiconductors Product specification
Line interrupter driver and ringer UBA1702; UBA1702A
FEATURES Speech part
Driver for the line interrupter that can be either a PMOST when UBA1702 is used or a PNP when UBA1702A is used
Adjustable over-current protection
Adjustable over-voltage protection for transmission
circuit
Adjustable mute (dialling mode voltage; DMO or NSA)
Adjustable current loop detection (hook switch status)
Microcontroller supply
Provision for electronic hook switch.
Ringer part
Over-voltage protection
Ringer frequency output for frequency discrimination
Adjustable ringer threshold for piezo-driver enable
Three bits ringer volume control
Bridge-tied-load (BTL) output stage for piezo transducer
Fast start-up microcontroller supply.
Miscellaneous
Separated ground pins for transmission circuit interface and control signals (e.g. for TEA1064A)
Possibility to supply the microcontroller with an external voltage source.
APPLICATIONS
Telephone sets with software controlled ringer function
Telephone sets with electronic hook switch.
GENERAL DESCRIPTION
The UBA1702; UBA1702A performs the high voltage interface and ringer functions of the corded analog telephone set in close cooperation with a microcontroller and transmission circuit.
The UBA1702; UBA1702A incorporates several protections, a driver for the line interrupter and a ringer. Because of the practical division of functions between the microcontroller, the transmission circuit and the UBA1702; UBA1702A, it is possible to have a higher integration level thereby reducing significantly the number of discrete components in a telephone set.
ORDERING INFORMATION
TYPE NUMBER
PACKAGE
NAME DESCRIPTION VERSION
UBA1702 DIP28 plastic dual in-line package; 28 leads (600 mil) SOT117-1 UBA1702A DIP28 plastic dual in-line package; 28 leads (600 mil) SOT117-1 UBA1702T SO28 plastic small outline package; 28 leads; body width 7.5 mm SOT136-1 UBA1702AT SO28 plastic small outline package; 28 leads; body width 7.5 mm SOT136-1
1997 Sep 29 3
Philips Semiconductors Product specification
Line interrupter driver and ringer UBA1702; UBA1702A
QUICK REFERENCE DATA
Speech part: l
line
= 20 mA; DPI = LOW; T
amb
=25°C; VEE= 0 V; unless otherwise specified.
Ringer part: V
line(rms)
= 45 V; f = 25 Hz; using an RC combination of 2.2 k and 820 nF and a diode bridge between the
line and the RPI input.
Notes
1. Independent of V
RR
if greater than 10 V.
2. Without piezo transducer, dependent on VRR.
SYMBOL PARAMETER CONDITIONS MIN. TYP. MAX. UNIT
Speech part
SWITCH DRIVER AND REFERENCES (PINS SDI, SDO, EHI AND DPI); UBA1702A ONLY R
SDO
resistance between pins SDO and V
EE
2.2 k SWITCH DRIVER AND REFERENCES (PINS SDI, SDO, EHI AND DPI); UBA1702 AND UBA1702A R
SDI-SDO
resistance between pins SDI and SDO V
SDI
V
SDO
<12V 1.1 M
R
SDI
resistance between pins SDI and V
EEVSDI
= 240 V; DPI = HIGH 5 −−M MUTE SWITCH AND ADJUSTABLE PROTECTION ZENER VOLTAGE (PINS MSI, MSA AND ZPA) V
SPO(M)
adjustable mute voltage referenced to V
EE
MSI = HIGH; MSA open-circuit
2.7 3 V
V
SPO(Z)
adjustable zener voltage referenced to V
EE
MSI = LOW; ZPA open-circuit
11 12 13 V
CURRENT MANAGEMENT (PINS SPI, SPO, CDA, CLA AND CDO) l
SPI(lim)
current limitation (pin SPI) CLA shorted to V
EE
120 mA
I
SPI(det)
current detection (pin SPI) CDA open-circuit 2 3 4 mA
MICROCONTROLLER SUPPLY (V
DD
AND V
BB
)
V
DD
supply output voltage referenced to V
SS
VBB> 3.7 V; IDD= 1 mA 3.0 3.3 3.6 V
Ringer part
P
ROTECTION (PIN RPI)
I
RPI(max)
maximum input current 70 −−mA RINGER THRESHOLD AND FREQUENCY DETECTION (PINS VRR,RTAAND RFO) V
RR(th)
ringer supply threshold voltage
referenced to V
SS
RTA open-circuit 11 V
VOLUME CONTROL (PINS RV0, RV1 AND RV2) G
s
step resolution (RV2, RV1, RV0) from
(0, 0, 0) to (1, 1, 0); note 1
6 dB
G
ls
last step resolution (RV2, RV1, RV0) from
(1, 1, 0) to (1, 1, 1); note 2
9.5 12 dB
RINGER MELODY INPUT AND PIEZO DRIVER (PINS RMI, ROA AND ROB) V
o(max pp)
maximum output voltage between pins
ROA and ROB (peak-to-peak value)
RV2=1; RV1=1; RV0=1 28.7 32 V
1997 Sep 29 4
Philips Semiconductors Product specification
Line interrupter driver and ringer UBA1702; UBA1702A
BLOCK DIAGRAM
Fig.1 Block diagram.
handbook, full pagewidth
MBE184
V
DD
V
SS
DIGITAL
-TO-
ANALOG
CONVERTER
V
DD
V
SS
V
DD
V
SS
V
DD
VOLUME
CONTROL
15
14
13
RV0
RV1
RV2
16
RINGER
THRESHOLD
11
R
ref
V
SS
RINGER MELODY INPUT AND PIEZO DRIVER
1/2 V
DD
V
DD
V
DD
V
RR
V
SS
V
RR
V
SS
22
ROA
ROB
20
R
ref
RINGER
PROTECTION
RPI
23
V
DD
V
SS
12
RINGER FREQUENCY
DETECTION
V
SS
SUPPLY
RINGER
V
DD
REFERENCES
V
ref
18
19
V
DD
V
BB
S
ref
R
ref
SPO
V
SS
UBA1702; UBA1702A UBA1702T; UBA1702AT
7
17
V
EE
V
SS
V
DD
V
SS
8
MSI
R
ref
MSA
S
ref
ZPA
MUTE SWITCH
ZENER PROTECTION
SPEECH
10
9
S
ref
SENSE
S
ref
V
DD
V
SS
LINE CURRENT MANAGEMENT
65262425
CLA
CDO
CDA
SPI
SPO
V
RR
RTA
21
RMI
SWITCH DRIVER
V
SS
14 V
21
SDI
SDO
DPI
EHI
4
28
RFO
V
RR
1997 Sep 29 5
Philips Semiconductors Product specification
Line interrupter driver and ringer UBA1702; UBA1702A
PINNING
SYMBOL PIN DESCRIPTION
SDI 1 switch driver input SDO 2 switch driver output n.c. 3 not connected DPI 4 dialling pulse input SPI 5 speech part input SPO 6 speech part output V
EE
7 ground for transmission circuit MSI 8 mute switch input ZPA 9 Zener protection adjustment input MSA 10 mute switch adjustment input RTA 11 ringer threshold adjustment input RFO 12 ringer frequency output RV0 13 ringer volume input; bit 0 RV1 14 ringer volume input; bit 1 RV2 15 ringer volume input; bit 2 RMI 16 ringer melody input V
SS
17 ground for microcontroller and
ringer
V
DD
18 microcontroller supply voltage
V
BB
19 supply voltage from transmission
circuit ROB 20 ringer output B V
RR
21 ringer supply voltage ROA 22 ringer output A RPI 23 ringer part input CDO 24 current detection output CLA 25 current limitation adjustment input CDA 26 current detection adjustment input n.c. 27 not connected EHI 28 electronic hook switch input
Fig.2 Pin configuration.
handbook, halfpage
1 2 3 4 5 6 7 8
9 10 11 12 13
28 27 26 25 24 23 22 21 20 19 18 17 16 1514
SDI
RV1
RV0
RFO
RTA
MSA
ZPA
V
SPO
DPI
n.c.
SDO
SPI
MSI
EE
RV2
RMI
ROB
V
ROA
RPI
CDO
CLA
CDA
n.c.
EHI
RR
V
BB
V
DD
V
SS
UBA1702 UBA1702T UBA1702A
UBA1702AT
MBE183
1997 Sep 29 6
Philips Semiconductors Product specification
Line interrupter driver and ringer UBA1702; UBA1702A
FUNCTIONAL DESCRIPTION
The values given in this functional description are typical values except when otherwise specified.
Speech part
The speech part consists of three blocks, the switch driver, the line current management and the mute switch (DMO or NSA) combined with an adjustable over-voltage (zener) protection circuit. The reference block, which generates reference voltages and currents, is also used in the speech part (see Fig.1) by the mute switch block.
S
WITCH DRIVER (PINS SDI, SDO, EHI AND DPI)
UBA1702
The UBA1702 switch driver block is intended to generate the appropriate signal to drive an external PMOST interrupter. The source and gate of this PMOST are respectively connected to SDI and SDO. The electronic hook switch input (EHI) and the dialling pulse input (DPI) signals control the state of this PMOST.
The EHI pin is provided with high voltage capability. When the voltage applied at pin EHI is HIGH, the switch driver block will start and generate the proper signals to switch on the external PMOST interrupter.
When the telephone set is equipped with a mechanical hook switch, pin EHI can be connected directly to the switch driver input (pin SDI). For electronic hook switch applications, the EHI pin can be driven by the microcontroller output.
In some special applications, the EHI pin can be current driven. In such a case, the current available at SDO to turn on the PMOST interrupter is approximately 10 times the EHI input current (providing I
EHI
<2µA).
The EHI pin presents an impedance of 250 k at low input voltage. When the applied voltage at EHI goes above approximately 30 V, the EHI input current remains constant (see Fig.3) so that the EHI impedance increases.
The DPI is designed to switch on or off the external PMOST interrupter (providing EHI is HIGH). When the voltage applied at pin DPI is HIGH, the switch driver block turns off the external PMOST interrupter. When the
voltage applied at pin DPI is LOW, the switch driver block turns on the external PMOST interrupter.
The external PMOST interrupter is controlled by the voltage between the switch driver input and output (pins SDI and SDO).
When the voltage applied at pin EHI is HIGH and the voltage applied at pin DPI is LOW, the voltage at SDO is pulled down to a value less than 0.2 V in order to create a high source-gate voltage (V
SG
) for the external PMOST. However, in order to avoid break-down of the external PMOST, the voltage difference between SDI and SDO is internally limited to 14 V.
When the voltage applied at pin EHI and the one applied at pin DPI are both HIGH, pin SDO can be considered as being connected to pin SDI via a 1.1 M pull-up resistor while the impedance between SDI and VEE becomes very high (a few MΩ).
When the voltage applied at pin EHI is LOW, whatever the one applied at DPI is, pin SDO can be considered as being connected to pin SDI via a 1.1 M pull-up resistor while the impedance between SDI and VEE becomes almost infinite.
Fig.3 EHI input characteristics.
handbook, halfpage
0 100 200 400
80
I
EHI
(µA)
60
20
0
40
MGD178
300
V
EHI
(V)
1997 Sep 29 7
Philips Semiconductors Product specification
Line interrupter driver and ringer UBA1702; UBA1702A
UBA1702A
The UBA1702A switch driver block is intended to generate the appropriate signal to drive an external PNP interrupter. The emitter and base of this PNP are respectively connected to SDI and SDO. The EHI and DPI signals control the state of this PNP.
The EHI pin is provided with high voltage capability. When the voltage applied at pin EHI is HIGH, the switch driver block will start and generate the appropriate signals to switch on the external PNP interrupter.
When the telephone set is equipped with a mechanical hook switch, pin EHI can be connected directly to pin SDI. For electronic hook switch applications, the EHI pin can be driven by the microcontroller output.
The EHI pin presents an impedance of 250 k at low input voltage. When the applied voltage at EHI goes above approximately 30 V, the EHI input current remains constant (see Fig.3) so that the EHI impedance increases.
The DPI is designed to switch on or off the external PNP interrupter (providing EHI is HIGH). When the voltage applied at pin DPI is HIGH, the switch driver block turns off the external PNP interrupter. When the voltage applied at pin DPI is LOW, the switch driver block turns on the external PNP interrupter.
The external PNP interrupter is controlled by the current flowing into pin SDO.
When the voltage applied at pin EHI is HIGH and the voltage applied at pin DPI is LOW, pin SDO can be considered as being connected to pin V
EE
via a 2.2 k resistor in order to create a base current for the external PNP.
When the voltage applied at pin EHI and the one applied at pin DPI are both HIGH, pin SDO can be considered as being connected to pin SDI via a 1.1 M pull-up resistor while the impedance between SDI and VEE becomes very high (a few MΩ).
When the voltage applied at pin EHI is LOW, whatever the one applied at DPI is, pin SDO can be considered as being connected to pin SDI via a 1.1 M pull-up resistor while the impedance between SDI and VEE becomes almost infinite.
L
INE CURRENT MANAGEMENT
(PINS SPI, SPO, CDA, CLA AND CDO) The line current is measured by an internal 2 resistor
and a sense circuit connected between the speech part input and output (pins SPI and SPO). The circuit delivers information about the hook switch status at the current detection output (pin CDO) and controls the line current limitation.
When the SPI current exceeds a certain level (3 mA), the sense circuit injects some image of the SPI current into an internal resistor (see Fig.1). The created voltage becomes higher than an internal reference (approximately 0.3 V) and CDO goes HIGH. This current detection level can be increased by connecting a resistor between pins CDA (current detection adjustment) and VEE. It is also possible to connect a capacitor between pins CDA and VEE to filter unwanted AC components of the line current signal. Line current interruption during pulse dialling influences the CDO output.
When the SPI current exceeds another current level (45 mA), the sense circuit injects some image of the SPI current into an internal resistor (see Fig.1). The created voltage becomes higher than an internal reference (approximately 0.4 V) and an internal signal is generated in order to limit the current in the external interrupter thus resulting in a line current limitation. This line current limitation level can be increased up to a maximum value of 120 mA by connecting a resistor between pins CLA (current limitation adjustment) and VEE.
When a PMOST (UBA1702) is used as an interrupter, the SPI current equals the drain or source current of the PMOST and thus also equals the line current.
When a PNP (UBA1702A) is used as an interrupter, the SPI current equals the collector current of the PNP and thus differs from the line current (the PNP base current does not flow into the SPI pin).
1997 Sep 29 8
Philips Semiconductors Product specification
Line interrupter driver and ringer UBA1702; UBA1702A
MUTE SWITCH AND ZENER PROTECTION (PINS MSI, MSA AND ZPA)
The mute switch is, in fact, a switchable and electronic zener diode connected between the speech part output (pin SPO) and VEE.
When the voltage applied at the mute switch input (pin MSI) is LOW, the switch is in over-voltage protection mode and the maximum SPO voltage is limited to 12 V. This level can be increased or decreased by connecting a resistor between pins ZPA (zener protection adjustment) and VEE or ZPA and SPO respectively.
When the voltage applied at pin MSI is HIGH, the switch is in mute mode (DMO or NSA) resulting in a SPO voltage below 3 V. This level can be decreased by connecting a resistor between pins MSA (mute switch adjustment) and SPO. It should be noted that the mute switch stage is supplied from VDD thus a minimum voltage of approximately 2.1 V is required on VDD.
R
EFERENCE
The bias currents and voltages for the various speech blocks are generated by the reference block which is, in most cases, supplied from pin SPO. This block guarantees a high AC impedance at the SPO pin operating down to a low SPO voltage. Therefore, most speech part blocks operate independently from VDD.
Ringer part
The ringer part consists of five blocks, the ringer protection, the ringer threshold, the ringer frequency detection, the volume control and the piezo driver. The reference block which generates reference voltages and currents is also used in the ringer part (see Fig.1).
R
INGER PROTECTION (PINS RPI AND V
RR
)
The ringer protection block converts the ringing current into a limited voltage between the ringer part input (pin RPI) and V
EE
. This voltage is used (via an internal diode) to generate the ringer supply voltage VRR which is mainly used for all ringer parts. The voltage at pin V
RR
must be filtered with a 22 µF capacitor connected between pins VRR and VSS.
In electronic hook switch applications and also in speech mode (see Fig.8), pin RPI is always connected to the telephone line (through a series RC network and a diode bridge). In order not to disturb normal speech operation, a high AC impedance is present at pin RPI (providing the speech level is less than 1.5 V (RMS) i.e. 5.7 dBm).
In the DMO or NSA mode (i.e. MSI is HIGH), the voltage across RPI and V
EE
is limited to 2.1 V. With this feature and in electronic hook switch applications, several additional ringers can be placed in parallel without tinkling during pulse dialling phase.
R
INGER THRESHOLD (PIN RTA)
The piezo driver is internally enabled when the voltage at pin VRR exceeds a threshold level of 11 V. This threshold level can be increased or decreased by connecting a resistor between pins RTA (ringer threshold adjustment) and V
SS
or RTA and VRR respectively.
Because of the built-in 6.5 V hysteresis, a voltage change at pin VRR (coming from current consumption increase when the piezo output is driven with a melody) will have no influence on this internal enabling signal.
R
INGER FREQUENCY DETECTION (PIN RFO)
The ringer frequency detection block generates a square wave signal at the ringer frequency output (pin RFO) with twice the ringer signal frequency. This RFO signal can be used by the microcontroller for frequency discrimination.
When the voltage at pin RPI drops below the voltage at pin VDD, RFO goes LOW. Pin RFO goes HIGH when the voltage at pin RPI exceeds the voltage at pin VRR. This VRR− VDD hysteresis allows the frequency detection circuit to ignore parasitic signals superimposed on the ringing signal.
The voltage at pin EHI must be LOW to get a square wave at pin RFO. When the voltage at pin EHI is LOW, the voltage at pin RFO is always HIGH whatever the one at pin RPI is.
V
OLUME CONTROL (PINS RV0, RV1 AND RV2)
The volume control input has three bits RV2, RV1 and RV0 to realize eight volume levels. The volume is controlled by regulating the supply voltage of the piezo output stage. The first six steps have a fixed value of 6 dB, the value of the last step (maximum volume) is dependent on the available voltage at pin VRR.
Default setting during start-up is (RV2 = 0, RV1 = 0, RV0 = 0) which corresponds to minimum volume. In order not to damage the piezo transducer, the differential output ROA ROB is internally limited to a value less than 32 V (p-p).
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