Source code for RsSmw.Implementations.Source.Iq.Output.Analog.Envelope

from .......Internal.Core import Core
from .......Internal.CommandsGroup import CommandsGroup
from .......Internal import Conversions
from ....... import enums


# noinspection PyPep8Naming,PyAttributeOutsideInit,SpellCheckingInspection
[docs]class EnvelopeCls: """Envelope commands group definition. 47 total commands, 7 Subgroups, 12 group commands""" def __init__(self, core: Core, parent): self._core = core self._cmd_group = CommandsGroup("envelope", core, parent) @property def emf(self): """emf commands group. 0 Sub-classes, 1 commands.""" if not hasattr(self, '_emf'): from .Emf import EmfCls self._emf = EmfCls(self._core, self._cmd_group) return self._emf @property def pin(self): """pin commands group. 0 Sub-classes, 2 commands.""" if not hasattr(self, '_pin'): from .Pin import PinCls self._pin = PinCls(self._core, self._cmd_group) return self._pin @property def power(self): """power commands group. 0 Sub-classes, 1 commands.""" if not hasattr(self, '_power'): from .Power import PowerCls self._power = PowerCls(self._core, self._cmd_group) return self._power @property def shaping(self): """shaping commands group. 6 Sub-classes, 3 commands.""" if not hasattr(self, '_shaping'): from .Shaping import ShapingCls self._shaping = ShapingCls(self._core, self._cmd_group) return self._shaping @property def vcc(self): """vcc commands group. 1 Sub-classes, 3 commands.""" if not hasattr(self, '_vcc'): from .Vcc import VccCls self._vcc = VccCls(self._core, self._cmd_group) return self._vcc @property def vout(self): """vout commands group. 0 Sub-classes, 2 commands.""" if not hasattr(self, '_vout'): from .Vout import VoutCls self._vout = VoutCls(self._core, self._cmd_group) return self._vout @property def vpp(self): """vpp commands group. 0 Sub-classes, 1 commands.""" if not hasattr(self, '_vpp'): from .Vpp import VppCls self._vpp = VppCls(self._core, self._cmd_group) return self._vpp # noinspection PyTypeChecker
[docs] def get_adaption(self) -> enums.IqOutEnvAdaption: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:ADAPtion \n Snippet: value: enums.IqOutEnvAdaption = driver.source.iq.output.analog.envelope.get_adaption() \n Defines the envelope voltage adaption mode. \n :return: adaption_mode: AUTO| MANual| POWer AUTO = Auto Normalized, POWer = Auto Power, MANual = Manual """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:ADAPtion?') return Conversions.str_to_scalar_enum(response, enums.IqOutEnvAdaption)
[docs] def set_adaption(self, adaption_mode: enums.IqOutEnvAdaption) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:ADAPtion \n Snippet: driver.source.iq.output.analog.envelope.set_adaption(adaption_mode = enums.IqOutEnvAdaption.AUTO) \n Defines the envelope voltage adaption mode. \n :param adaption_mode: AUTO| MANual| POWer AUTO = Auto Normalized, POWer = Auto Power, MANual = Manual """ param = Conversions.enum_scalar_to_str(adaption_mode, enums.IqOutEnvAdaption) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:ADAPtion {param}')
[docs] def get_bias(self) -> float: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:BIAS \n Snippet: value: float = driver.source.iq.output.analog.envelope.get_bias() \n Sets a bias. \n :return: bias: float Range: -3.390V to 3.990V (R&S SMW-B10) / -0.2V to 2.5V (R&S SMW-B9) , Unit: V """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:BIAS?') return Conversions.str_to_float(response)
[docs] def set_bias(self, bias: float) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:BIAS \n Snippet: driver.source.iq.output.analog.envelope.set_bias(bias = 1.0) \n Sets a bias. \n :param bias: float Range: -3.390V to 3.990V (R&S SMW-B10) / -0.2V to 2.5V (R&S SMW-B9) , Unit: V """ param = Conversions.decimal_value_to_str(bias) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:BIAS {param}')
[docs] def get_binput(self) -> bool: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:BINPut \n Snippet: value: bool = driver.source.iq.output.analog.envelope.get_binput() \n Enables the generation of a bipolar signal. \n :return: bipolar_input: 1| ON| 0| OFF """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:BINPut?') return Conversions.str_to_bool(response)
[docs] def set_binput(self, bipolar_input: bool) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:BINPut \n Snippet: driver.source.iq.output.analog.envelope.set_binput(bipolar_input = False) \n Enables the generation of a bipolar signal. \n :param bipolar_input: 1| ON| 0| OFF """ param = Conversions.bool_to_str(bipolar_input) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:BINPut {param}')
[docs] def get_delay(self) -> float: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:DELay \n Snippet: value: float = driver.source.iq.output.analog.envelope.get_delay() \n Enables a time delay of the generated envelope signal relative to the corresponding RF signal. \n :return: delay: float Range: -500E-9 to 500E-9 """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:DELay?') return Conversions.str_to_float(response)
[docs] def set_delay(self, delay: float) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:DELay \n Snippet: driver.source.iq.output.analog.envelope.set_delay(delay = 1.0) \n Enables a time delay of the generated envelope signal relative to the corresponding RF signal. \n :param delay: float Range: -500E-9 to 500E-9 """ param = Conversions.decimal_value_to_str(delay) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:DELay {param}')
# noinspection PyTypeChecker
[docs] def get_etrak(self) -> enums.IqOutEnvEtRak: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:ETRak \n Snippet: value: enums.IqOutEnvEtRak = driver.source.iq.output.analog.envelope.get_etrak() \n Selects one of the predefined interface types or allows user-defined settings. See Table 'Default parameters per eTrak(R) Interface Type'. \n :return: etrak_ifc_type: USER| ET1V2| ET1V5| ET2V0 """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:ETRak?') return Conversions.str_to_scalar_enum(response, enums.IqOutEnvEtRak)
[docs] def set_etrak(self, etrak_ifc_type: enums.IqOutEnvEtRak) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:ETRak \n Snippet: driver.source.iq.output.analog.envelope.set_etrak(etrak_ifc_type = enums.IqOutEnvEtRak.ET1V2) \n Selects one of the predefined interface types or allows user-defined settings. See Table 'Default parameters per eTrak(R) Interface Type'. \n :param etrak_ifc_type: USER| ET1V2| ET1V5| ET2V0 """ param = Conversions.enum_scalar_to_str(etrak_ifc_type, enums.IqOutEnvEtRak) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:ETRak {param}')
[docs] def get_fdpd(self) -> bool: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:FDPD \n Snippet: value: bool = driver.source.iq.output.analog.envelope.get_fdpd() \n Enables calculation of the envelope from predistorted signal. \n :return: calc_from_dpd_stat: 1| ON| 0| OFF """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:FDPD?') return Conversions.str_to_bool(response)
[docs] def set_fdpd(self, calc_from_dpd_stat: bool) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:FDPD \n Snippet: driver.source.iq.output.analog.envelope.set_fdpd(calc_from_dpd_stat = False) \n Enables calculation of the envelope from predistorted signal. \n :param calc_from_dpd_stat: 1| ON| 0| OFF """ param = Conversions.bool_to_str(calc_from_dpd_stat) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:FDPD {param}')
[docs] def get_gain(self) -> float: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:GAIN \n Snippet: value: float = driver.source.iq.output.analog.envelope.get_gain() \n Sets the gain of the used external DC modulator. \n :return: gain: float Range: -50 to 50 """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:GAIN?') return Conversions.str_to_float(response)
[docs] def set_gain(self, gain: float) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:GAIN \n Snippet: driver.source.iq.output.analog.envelope.set_gain(gain = 1.0) \n Sets the gain of the used external DC modulator. \n :param gain: float Range: -50 to 50 """ param = Conversions.decimal_value_to_str(gain) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:GAIN {param}')
[docs] def get_offset(self) -> float: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:OFFSet \n Snippet: value: float = driver.source.iq.output.analog.envelope.get_offset() \n Sets an offset between the envelope and the inverted envelope signal. \n :return: offset: float Range: (-4+Vp/2+Vbias/2) ,V to (4-Vp/2-Vbias/2) ,V (R&S SMW-B10) / -2V to 2V (R&S SMW-B9) , Unit: V """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:OFFSet?') return Conversions.str_to_float(response)
[docs] def set_offset(self, offset: float) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:OFFSet \n Snippet: driver.source.iq.output.analog.envelope.set_offset(offset = 1.0) \n Sets an offset between the envelope and the inverted envelope signal. \n :param offset: float Range: (-4+Vp/2+Vbias/2) ,V to (4-Vp/2-Vbias/2) ,V (R&S SMW-B10) / -2V to 2V (R&S SMW-B9) , Unit: V """ param = Conversions.decimal_value_to_str(offset) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:OFFSet {param}')
[docs] def get_rin(self) -> float: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:RIN \n Snippet: value: float = driver.source.iq.output.analog.envelope.get_rin() \n Sets the input impedance Rin of the used external DC modulator. \n :return: ipart_nput_resistance: No help available """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:RIN?') return Conversions.str_to_float(response)
[docs] def set_rin(self, ipart_nput_resistance: float) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:RIN \n Snippet: driver.source.iq.output.analog.envelope.set_rin(ipart_nput_resistance = 1.0) \n Sets the input impedance Rin of the used external DC modulator. \n :param ipart_nput_resistance: float Range: 50|100 to 1E6 """ param = Conversions.decimal_value_to_str(ipart_nput_resistance) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:RIN {param}')
[docs] def get_state(self) -> bool: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:STATe \n Snippet: value: bool = driver.source.iq.output.analog.envelope.get_state() \n Enables the output of a control signal that follows the RF envelope. \n :return: state: 1| ON| 0| OFF """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:STATe?') return Conversions.str_to_bool(response)
[docs] def set_state(self, state: bool) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:STATe \n Snippet: driver.source.iq.output.analog.envelope.set_state(state = False) \n Enables the output of a control signal that follows the RF envelope. \n :param state: 1| ON| 0| OFF """ param = Conversions.bool_to_str(state) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:STATe {param}')
# noinspection PyTypeChecker
[docs] def get_termination(self) -> enums.IqOutEnvTerm: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:TERMination \n Snippet: value: enums.IqOutEnvTerm = driver.source.iq.output.analog.envelope.get_termination() \n Sets how the inputs of the DC modulator are terminated. \n :return: termination: GROund| WIRE """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:TERMination?') return Conversions.str_to_scalar_enum(response, enums.IqOutEnvTerm)
[docs] def set_termination(self, termination: enums.IqOutEnvTerm) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:TERMination \n Snippet: driver.source.iq.output.analog.envelope.set_termination(termination = enums.IqOutEnvTerm.GROund) \n Sets how the inputs of the DC modulator are terminated. \n :param termination: GROund| WIRE """ param = Conversions.enum_scalar_to_str(termination, enums.IqOutEnvTerm) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:TERMination {param}')
# noinspection PyTypeChecker
[docs] def get_vref(self) -> enums.IqOutEnvVrEf: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:VREF \n Snippet: value: enums.IqOutEnvVrEf = driver.source.iq.output.analog.envelope.get_vref() \n Defines whether the envelope voltage Vout is set directly or it is estimated from the selected supply voltage Vcc. \n :return: voltage_reference: VCC| VOUT """ response = self._core.io.query_str('SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:VREF?') return Conversions.str_to_scalar_enum(response, enums.IqOutEnvVrEf)
[docs] def set_vref(self, voltage_reference: enums.IqOutEnvVrEf) -> None: """SCPI: [SOURce<HW>]:IQ:OUTPut:[ANALog]:ENVelope:VREF \n Snippet: driver.source.iq.output.analog.envelope.set_vref(voltage_reference = enums.IqOutEnvVrEf.VCC) \n Defines whether the envelope voltage Vout is set directly or it is estimated from the selected supply voltage Vcc. \n :param voltage_reference: VCC| VOUT """ param = Conversions.enum_scalar_to_str(voltage_reference, enums.IqOutEnvVrEf) self._core.io.write(f'SOURce<HwInstance>:IQ:OUTPut:ANALog:ENVelope:VREF {param}')
def clone(self) -> 'EnvelopeCls': """Clones the group by creating new object from it and its whole existing subgroups Also copies all the existing default Repeated Capabilities setting, which you can change independently without affecting the original group""" new_group = EnvelopeCls(self._core, self._cmd_group.parent) self._cmd_group.synchronize_repcaps(new_group) return new_group