Head-related transfer function

HRTF filtering effect

A head-related transfer function (HRTF) is a response that characterizes how an ear receives a sound from a point in space. As sound strikes the listener, the size and shape of the head, ears, ear canal, density of the head, size and shape of nasal and oral cavities, all transform the sound and affect how it is perceived, boosting some frequencies and attenuating others. Generally speaking, the HRTF boosts frequencies from 2–5 kHz with a primary resonance of +17 dB at 2,700 Hz. But the response curve is more complex than a single bump, affects a broad frequency spectrum, and varies significantly from person to person.

A pair of HRTFs for two ears can be used to synthesize a binaural sound that seems to come from a particular point in space. It is a transfer function, describing how a sound from a specific point will arrive at the ear (generally at the outer end of the auditory canal). Some consumer home entertainment products designed to reproduce surround sound from stereo (two-speaker) headphones use HRTFs. Some forms of HRTF processing have also been included in computer software to simulate surround sound playback from loudspeakers.

Sound localization

Humans have just two ears, but can locate sounds in three dimensions – in range (distance), in direction above and below (elevation), in front and to the rear, as well as to either side (azimuth). This is possible because the brain, inner ear, and the external ears (pinna) work together to make inferences about location. This ability to localize sound sources may have developed in humans and ancestors as an evolutionary necessity since the eyes can only see a fraction of the world around a viewer, and vision is hampered in darkness, while the ability to localize a sound source works in all directions, to varying accuracy,[1] regardless of the surrounding light.

Humans estimate the location of a source by taking cues derived from one ear (monaural cues), and by comparing cues received at both ears (difference cues or binaural cues). Among the difference cues are time differences of arrival and intensity differences. The monaural cues come from the interaction between the sound source and the human anatomy, in which the original source sound is modified before it enters the ear canal for processing by the auditory system. These modifications encode the source location and may be captured via an impulse response which relates the source location and the ear location. This impulse response is termed the head-related impulse response (HRIR). Convolution of an arbitrary source sound with the HRIR converts the sound to that which would have been heard by the listener if it had been played at the source location, with the listener's ear at the receiver location. HRIRs have been used to produce virtual surround sound.[2][3] [example needed]

The HRTF is the Fourier transform of HRIR.

HRTFs for left and right ear (expressed above as HRIRs) describe the filtering of a sound source (x(t)) before it is perceived at the left and right ears as xL(t) and xR(t), respectively.

The HRTF can also be described as the modifications to a sound from a direction in free air to the sound as it arrives at the eardrum. These modifications include the shape of the listener's outer ear, the shape of the listener's head and body, the acoustic characteristics of the space in which the sound is played, and so on. All these characteristics will influence how (or whether) a listener can accurately tell what direction a sound is coming from.

In the AES69-2015 standard,[4] the Audio Engineering Society (AES) has defined the SOFA file format for storing spatially oriented acoustic data like head-related transfer functions (HRTFs). SOFA software libraries and files are collected at the Sofa Conventions website.[5]

How HRTF works

The associated mechanism varies between individuals, as their head and ear shapes differ.

HRTF describes how a given sound wave input (parameterized as frequency and source location) is filtered by the diffraction and reflection properties of the head, pinna, and torso, before the sound reaches the transduction machinery of the eardrum and inner ear (see auditory system). Biologically, the source-location-specific prefiltering effects of these external structures aid in the neural determination of source location, particularly the determination of the source's elevation.[6]

Technical derivation

A sample of frequency response of ears:
  • green curve: left ear   XL(f)
  • blue curve:   right ear XR(f)
for a sound source from upward front.
An example of how the HRTF tilt with azimuth taken from a point of reference is derived

Linear systems analysis defines the transfer function as the complex ratio between the output signal spectrum and the input signal spectrum as a function of frequency. Blauert (1974; cited in Blauert, 1981) initially defined the transfer function as the free-field transfer function (FFTF). Other terms include free-field to eardrum transfer function and the pressure transformation from the free-field to the eardrum. Less specific descriptions include the pinna transfer function, the outer ear transfer function, the pinna response, or directional transfer function (DTF).

The transfer function H(f) of any linear time-invariant system at frequency f is:

H(f) = Output(f) / Input(f)

One method used to obtain the HRTF from a given source location is therefore to measure the head-related impulse response (HRIR), h(t), at the ear drum for the impulse Δ(t) placed at the source. The HRTF H(f) is the Fourier transform of the HRIR h(t).

Even when measured for a "dummy head" of idealized geometry, HRTF are complicated functions of frequency and the three spatial variables. For distances greater than 1 m from the head, however, the HRTF can be said to attenuate inversely with range. It is this far field HRTF, H(f, θ, φ), that has most often been measured. At closer range, the difference in level observed between the ears can grow quite large, even in the low-frequency region within which negligible level differences are observed in the far field.

HRTFs are typically measured in an anechoic chamber to minimize the influence of early reflections and reverberation on the measured response. HRTFs are measured at small increments of θ such as 15° or 30° in the horizontal plane, with interpolation used to synthesize HRTFs for arbitrary positions of θ. Even with small increments, however, interpolation can lead to front-back confusion, and optimizing the interpolation procedure is an active area of research.

In order to maximize the signal-to-noise ratio (SNR) in a measured HRTF, it is important that the impulse being generated be of high volume. In practice, however, it can be difficult to generate impulses at high volumes and, if generated, they can be damaging to human ears, so it is more common for HRTFs to be directly calculated in the frequency domain using a frequency-swept sine wave or by using maximum length sequences. User fatigue is still a problem, however, highlighting the need for the ability to interpolate based on fewer measurements.

The head-related transfer function is involved in resolving the cone of confusion, a series of points where interaural time difference (ITD) and interaural level difference (ILD) are identical for sound sources from many locations around the 0 part of the cone. When a sound is received by the ear it can either go straight down the ear into the ear canal or it can be reflected off the pinnae of the ear, into the ear canal a fraction of a second later. The sound will contain many frequencies, so therefore many copies of this signal will go down the ear all at different times depending on their frequency (according to reflection, diffraction, and their interaction with high and low frequencies and the size of the structures of the ear.) These copies overlap each other, and during this, certain signals are enhanced (where the phases of the signals match) while other copies are canceled out (where the phases of the signal do not match). Essentially, the brain is looking for frequency notches in the signal that correspond to particular known directions of sound.[citation needed]

If another person's ears were substituted, the individual would not immediately be able to localize sound, as the patterns of enhancement and cancellation would be different from those patterns the person's auditory system is used to. However, after some weeks, the auditory system would adapt to the new head-related transfer function.[7] The inter-subject variability in the spectra of HRTFs has been studied through cluster analyses.[8]

Assessing the variation through changes between the person's ear, we can limit our perspective with the degrees of freedom of the head and its relation with the spatial domain. Through this, we eliminate the tilt and other co-ordinate parameters that add complexity. For the purpose of calibration we are only concerned with the direction level to our ears, ergo a specific degree of freedom. Some of the ways in which we can deduce an expression to calibrate the HRTF are:

  1. Localization of sound in Virtual Auditory space[9]
  2. HRTF Phase synthesis[10]
  3. HRTF Magnitude synthesis[11]

Localization of sound in virtual auditory space

A basic assumption in the creation of a virtual auditory space is that if the acoustical waveforms present at a listener's eardrums are the same under headphones as in free field, then the listener's experience should also be the same.

Typically, sounds generated from headphones are perceived as originating from within the head. In the virtual auditory space, the headphones should be able to "externalize" the sound. Using the HRTF, sounds can be spatially positioned using the technique described below.[9]

Let x1(t) represent an electrical signal driving a loudspeaker and y1(t) represent the signal received by a microphone inside the listener's eardrum. Similarly, let x2(t) represent the electrical signal driving a headphone and y2(t) represent the microphone response to the signal. The goal of the virtual auditory space is to choose x2(t) such that y2(t) = y1(t). Applying the Fourier transform to these signals, we come up with the following two equations:

Y1 = X1LFM, and
Y2 = X2HM,

where L is the transfer function of the loudspeaker in the free field, F is the HRTF, M is the microphone transfer function, and H is the headphone-to-eardrum transfer function. Setting Y1 = Y2, and solving for X2 yields

X2 = X1LF/H.

By observation, the desired transfer function is

T= LF/H.

Therefore, theoretically, if x1(t) is passed through this filter and the resulting x2(t) is played on the headphones, it should produce the same signal at the eardrum. Since the filter applies only to a single ear, another one must be derived for the other ear. This process is repeated for many places in the virtual environment to create an array of head-related transfer functions for each position to be recreated while ensuring that the sampling conditions are set by the Nyquist criteria.

HRTF phase synthesis

There is less reliable phase estimation in the very low part of the frequency band, and in the upper frequencies the phase response is affected by the features of the pinna. Earlier studies also show that the HRTF phase response is mostly linear and that listeners are insensitive to the details of the interaural phase spectrum as long as the interaural time delay (ITD) of the combined low-frequency part of the waveform is maintained. This is the modeled phase response of the subject HRTF as a time delay, dependent on the direction and elevation.[10]

A scaling factor is a function of the anthropometric features. For example, a training set of N subjects would consider each HRTF phase and describe a single ITD scaling factor as the average delay of the group. This computed scaling factor can estimate the time delay as function of the direction and elevation for any given individual. Converting the time delay to phase response for the left and the right ears is trivial.

The HRTF phase can be described by the ITD scaling factor. This is in turn quantified by the anthropometric data of a given individual taken as the source of reference. For a generic case we consider β as a sparse vector

that represents the subject's anthropometric features as a linear superposition of the anthropometric features from the training data (y' = βT X), and then apply the same sparse vector directly on the scaling vector H. We can write this task as a minimization problem, for a non-negative shrinking parameter λ:

From this, ITD scaling factor value H' is estimated as:

where The ITD scaling factors for all persons in the dataset are stacked in a vector HRN, so the value Hn corresponds to the scaling factor of the n-th person.

HRTF magnitude synthesis

We solve the above minimization problem using least absolute shrinkage and selection operator. We assume that the HRTFs are represented by the same relation as the anthropometric features.[11] Therefore, once we learn the sparse vector β from the anthropometric features, we directly apply it to the HRTF tensor data and the subject's HRTF values H' given by:

where The HRTFs for each subject are described by a tensor of size D × K, where D is the number of HRTF directions and K is the number of frequency bins. All Hn,d,k corresponds to all the HRTFs of the training set are stacked in a new tensor HRN×D×K, so the value Hn,d,k corresponds to the k-th frequency bin for d-th HRTF direction of the n-th person. Also H'd,k corresponds to k-th frequency for every d-th HRTF direction of the synthesized HRTF.

HRTF from geometry

Accumulation of HRTF data has made it possible for a computer program to infer an approximate HRTF from head geometry. Two programs are known to do so, both open-source: Mesh2HRTF,[12] which runs physical simulation on a full 3D-mesh of the head, and EAC, which uses a neural network trained from existing HRTFs and works from photo and other rough measurements.[13]

Recording and playback technology

Recordings processed via an HRTF, such as in a computer gaming environment (see A3D, EAX, and OpenAL), which approximates the HRTF of the listener, can be heard through stereo headphones or speakers and interpreted as if they comprise sounds coming from all directions, rather than just two points on either side of the head. The perceived accuracy of the result depends on how closely the HRTF data set matches the characteristics of one's own ears, though a generic HRTF may be preferred to an accurate one measured from one's one ear.[14] Some vendors like Apple and Sony offer a variety of HRTFs to be selected by the user's ear shape.[15]

Windows 10 and above come with Microsoft Spatial Sound included, the same spatial audio framework used on Xbox One and Hololens 2. On a Windows PC or an Xbox One, the framework can use several different downstream audio processors, including Windows Sonic for Headphones, Dolby Atmos, and DTS Headphone:X, to apply an HRTF. The framework can render both fixed-position surround sound sources and dynamic "object" sources that can move in space.[16]

Apple similarly has Spatial Sound for its devices used with headphones produced by Apple or Beats. For music playback to headphones, Dolby Atmos can be enabled and the HRTF applied.[17] The HRTF (or rather, the object positions) can vary with head tracking to maintain the illusion of direction.[18] Qualcomm Snapdragon has a similar head-tracked spatial audio system, used by some brands of Android phones.[19] YouTube uses head-tracked HRTF with 360-degree and VR videos.[20]

Linux is currently unable to directly process any of the proprietary spatial audio (surround plus dynamic objects) formats. SoundScape Renderer offers directional synthesis.[21] PulseAudio and PipeWire each can provide virtual surround (fixed-location channels) using an HRTF. Recent PipeWire versions are also able to provide dynamic spatial rendering using HRTFs,[22] however integration with applications is still in progress. Users can configure their own positional and dynamic sound sources, as well as simulate a surround speaker setup using existing configurations.

The cross-platform OpenAL Soft, an implementation of OpenAL, uses HRTFs for improved localization.[23]

Windows and Linux spatial audio systems support any model of stereo headphones, while Apple only allows spatial audio to be used with Apple or Beats-branded Bluetooth headsets.[citation needed]

See also

References

  1. ^ Daniel Starch (1908). Perimetry of the localization of sound. State University of Iowa. p. 35 ff.
  2. ^ Begault, D.R. (1994) 3D sound for virtual reality and multimedia. AP Professional.
  3. ^ So, R.H.Y., Leung, N.M., Braasch, J. and Leung, K.L. (2006) A low cost, Non-individualized surround sound system based upon head-related transfer functions. An Ergonomics study and prototype development. Applied Ergonomics, 37, pp. 695–707.
  4. ^ "AES Standard AES69-2015: AES standard for file exchange - Spatial acoustic data file format". www.aes.org. Retrieved 2016-12-30.
  5. ^ "Sofa Conventions Website". Acoustics Research Institute, a research institute of the Austrian Academy of Sciences.
  6. ^ Blauert, J. (1997) Spatial hearing: the psychophysics of human sound localization. MIT Press.
  7. ^ Hofman, Paul M.; Van Riswick, JG; Van Opstal, AJ (September 1998). "Relearning sound localization with new ears" (PDF). Nature Neuroscience. 1 (5): 417–421. doi:10.1038/1633. PMID 10196533. S2CID 10088534.
  8. ^ So, R.H.Y., Ngan, B., Horner, A., Leung, K.L., Braasch, J. and Blauert, J. (2010) Toward orthogonal non-individualized head-related transfer functions for forward and backward directional sound: cluster analysis and an experimental study. Ergonomics, 53(6), pp.767-781.
  9. ^ a b Carlile, S. (1996). Virtual Auditory Space: Generation and Applications (1 ed.). Berlin, Heidelberg: Springer. ISBN 9783662225967.
  10. ^ a b Tashev, Ivan (2014). "HRTF phase synthesis via sparse representation of anthropometric features". 2014 Information Theory and Applications Workshop (ITA). pp. 1–5. doi:10.1109/ITA.2014.6804239. ISBN 978-1-4799-3589-5. S2CID 13232557.
  11. ^ a b Bilinski, Piotr; Ahrens, Jens; Thomas, Mark RP; Tashev, Ivan; Platt, John C (2014). "HRTF magnitude synthesis via sparse representation of anthropometric features" (PDF). 2014 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP). IEEE ICASSP, Florence, Italy. pp. 4468–4472. doi:10.1109/ICASSP.2014.6854447. ISBN 978-1-4799-2893-4. S2CID 5619011.
  12. ^ Ziegelwanger, H., and Kreuzer, W., Majdak, P. (2015). "Mesh2HRTF: An open-source software package for the numerical calculation of head-related transfer functions," in Proceedings of the 22nd International Congress on Sound and Vibration, Florence, Italy.
  13. ^ Carvalho, Davi (17 April 2023). "EAC - Individualized HRTF Synthesis". GitHub.
  14. ^ Armstrong, Cal; Thresh, Lewis; Murphy, Damian; Kearney, Gavin (23 October 2018). "A Perceptual Evaluation of Individual and Non-Individual HRTFs: A Case Study of the SADIE II Database". Applied Sciences. 8 (11): 2029. doi:10.3390/app8112029.
  15. ^ "Spatial Audio: Part 1 - Current Formats & The Rise Of HRTF - The Broadcast Bridge - Connecting IT to Broadcast". The Broadcast Bridge. 7 December 2022.
  16. ^ "Spatial Sound for app developers for Windows, Xbox, and Hololens 2 - Win32 apps". learn.microsoft.com. 27 April 2023.
  17. ^ "About Spatial Audio with Dolby Atmos in Apple Music". Apple Support. 27 March 2023.
  18. ^ "Listen with spatial audio for AirPods and Beats". Apple Support. 19 July 2023.
  19. ^ "Spatial Audio". www.qualcomm.com.
  20. ^ "Use spatial audio in 360-degree and VR videos - YouTube Help". support.google.com.
  21. ^ "SoundScape Renderer". spatialaudio.net. 9 January 2013.
  22. ^ "Filter Chain". gitlab.freedesktop.org/pipewire/pipewire. 14 April 2023.
  23. ^ "OpenAL Soft - Software 3D Audio". openal-soft.org.

Read other articles:

Putri Margaret dari Denmark (Margrethe Francoise Louise Marie Helene; 17 September 1895 – 18 September 1992) adalah seorang putri Denmark melalui kelahirannya dan seorang putri dari Bourbon-Parma sebagai istri dari Pangeran Rene dari Bourbon-Parma. Putri MargaretPutri Rene dari Bourbon-ParmaKelahiran(1895-09-17)17 September 1895Istana Bernstorff, Gentofte, DenmarkKematian18 September 1992(1992-09-18) (umur 97)Kopenhagen, DenmarkNama lengkapMargrethe Francoise Louise Marie HeleneAyahPan...

 

Pertapaan GedonoInformasi biaraNama lengkapPertapaan Bunda Pemersatu GedonoOrdoTrapis (OCSO)Didirikan12 April 1987Biara indukPertapaan Santa Maria Rawaseneng, TemanggungDidedikasikan kepadaMaria Bunda PemersatuKeuskupanKeuskupan Agung SemarangTokohPendiriDom Frans Harjawiyata, OCSOAbbasIbu Abdis Martha Elisabeth Driscoll, OCSOTokoh penting yang terkaitIbu Abdis Cristiana Piccardo, OCSORomo Suitbertus Ari Sunardi OCSOArsitekturArsitekRD Y.B. MangunwijayaSitusLokasiDusun Weru,Desa Jetak,Getasan...

 

1958 1969 Élection présidentielle française de 1965 5 décembre 1965 (1er tour)19 décembre 1965 (2d tour) Corps électoral et résultats Population 48 952 282 Inscrits au 1er tour 28 910 581 Votants au 1er tour 24 502 916   84,75 % Votes exprimés au 1er tour 24 254 556 Blancs et nuls au 1er tour 248 360 Inscrits au 2d tour 28 902 704 Votants au 2d tour 24 371 647   84,32 % Votes exprimés ...

Gambar Tari Moyo Tari Moyo atau disebut juga sebagai tari elang merupakan salah satu seni tari tradisional yang berasal dari pulau Nias, provinsi Sumatera Utara, Indonesia. Secara etimologi, Moyo dalam bahasa Nias berarti burung elang. Hewan unggas tersebut adalah ilham bagi masyarakat nias dalam menciptakan gerakan tarian ini yang menggambarkan seekor burung elang yang mengepakkan sayapnya, tanpa mengenal lelah, menaklukkan sesuatu yang bermakna bagi sesamanya dan dirinya sendiri. Pada dasar...

 

Wooden LegacyFormerlyWooden Classic and DirecTV ClassicSportCollege BasketballFounded2013No. of teams8 (2013–2019)4 (2020–present)Most recentchampion(s)BYUSponsor(s)PaycomOfficial websitewooden legacy The Paycom Wooden Legacy is an annual early-season men's college basketball competition that began in 2013. It is named in honor of basketball coach John Wooden, whose UCLA Bruins teams won 10 national championships over the 12 seasons from 1964 to 1975. History and format The Wooden Legacy ...

 

American diplomat and academic (born 1956) R. Nicholas BurnsOfficial portrait, 202213th United States Ambassador to ChinaIncumbentAssumed office April 1, 2022PresidentJoe BidenPreceded byTerry BranstadUnder Secretary of State for Political AffairsIn officeMarch 18, 2005 – February 29, 2008PresidentGeorge W. BushPreceded byMarc GrossmanSucceeded byWilliam J. BurnsUnited States Ambassador to NATOIn officeAugust 7, 2001 – March 7, 2005PresidentGeorge W. BushPreceded byS...

Yosaphat Didik Heru Purnomo Laksamana Madya TNI (Purnawirawan) Informasi pribadiLahir14 April 1954 (umur 70) YogyakartaAlma materAKABRI (1975)PekerjaanPurnawirawan TNIKarier militerPihak IndonesiaDinas/cabang TNI Angkatan LautMasa dinas1975 – 2012Pangkat Laksamana Madya TNINRP7415/PSatuanKorps PelautSunting kotak info • L • B Laksamana Madya TNI (Purn.) Yosaphat Didik Heru Purnomo (lahir 14 April 1954) adalah seorang purnawirawan perwira tinggi militer dari TNI ...

 

CangkuangDesaNegara IndonesiaProvinsiJawa BaratKabupatenGarutKecamatanLelesKode Kemendagri32.05.09.2006 Luas... km²Jumlah penduduk9.624 jiwaKepadatan... jiwa/km² Rekreasi di danau Cangkuang (tahun 1910-1927) Cangkuang adalah desa di kecamatan Leles, Garut, Jawa Barat, Indonesia. Pranala luar (Indonesia) Keputusan Menteri Dalam Negeri Nomor 050-145 Tahun 2022 tentang Pemberian dan Pemutakhiran Kode, Data Wilayah Administrasi Pemerintahan, dan Pulau tahun 2021 (Indonesia) Peraturan Mente...

 

Village in West Yorkshire, England Human settlement in EnglandTongVillage hall on Tong LaneTongLocation within West YorkshireOS grid referenceSE221307Metropolitan boroughCity of BradfordMetropolitan countyWest YorkshireRegionYorkshire and the HumberCountryEnglandSovereign stateUnited KingdomPost townBRADFORDPostcode districtBD4Dialling code01274PoliceWest YorkshireFireWest YorkshireAmbulanceYorkshire UK ParliamentBradford South List of places UK England...

Pour les articles homonymes, voir Palcy. Euzhan PalcyEuzhan Palcy à la cérémonie des prix Lumières en 2012BiographieNaissance 13 janvier 1958 (66 ans)Gros-MorneNationalité françaiseDomicile ParisFormation Faculté des lettres de ParisÉcole nationale supérieure Louis-Lumière (diplôme d'études approfondies)Activités Réalisatrice, scénariste, productrice de cinémaAutres informationsMembre de Comité pour la mémoire et l'histoire de l'esclavage (2013)Site web (en) www.e...

 

Barony in the Peerage of the United Kingdom Baron CarrickfergusIncumbentWilliamsince 29 April 2011Term lengthLife tenure or until accession as Sovereign Baron Carrickfergus is a title in the peerage of the United Kingdom, referring to Carrickfergus in County Antrim, Northern Ireland. Its current holder, since its creation on 29 April 2011, is William, Prince of Wales, who was granted the title as a personal gift by Elizabeth II, on the day of his marriage to Catherine Middleton.[1 ...

 

Universitas Kahuripan KediriJenisPerguruan Tinggi SwastaDidirikan1999RektorHarry Sugara, M.Pd[1]LokasiPare, Kediri, Jawa Timur, IndonesiaWarnaBiruSitus webwww.kahuripan.ac.id Universitas Kahuripan Kediri (disingkat UKK) adalah sebuah Perguruan Tinggi Swasta di Pare, Kediri, Kediri, Jawa Timur, Indonesia. Rektor pada saat ini (2023) adalah Harry Sugara, M.Pd Sejarah Sejarah Universitas Kahuripan Kediri dimulai pada tahun 1999 dengan berdirinya Sekolah Tinggi Ilmu Ekonomi (STIE) Canda B...

Mappa dell'Eurozona      Zona euro      UE appartenenti agli AEC II      UE appartenenti agli AEC II con deroga      UE non appartenenti agli AEC II      Non UE che usano bilateralmente l'euro      Non UE che usano unilateralmente l'euro Voce principale: Monete in euro. Le monete euro lituane sono in circolazione dal 1º gennaio 2015. La...

 

Defunct flying squadron of the Royal Air Force No. 102 (Ceylon) Squadron RAFNo. 102 Squadron badgeActive9 Aug 1917 – 3 Jul 1919 1 Oct 1935 – 28 Feb 1946 20 Oct 1954 – 20 Aug 1956 1 Aug 1959 – 27 Apr 1963[1]Country United KingdomBranch Royal Air ForceNickname(s)Ceylon[2]Morecambe's 'own' Squadron[3] (Unofficial)Motto(s)Latin: Tentate et Perficite(Attempt and achieve)[2][3]InsigniaSquadron Badge heraldryOn a demi-terrestrial globe a lion rampant g...

 

Norah Lange Norah Lange (Buenos Aires, 23 ottobre 1905 – Buenos Aires, 4 agosto 1972) è stata una scrittrice e poetessa argentina. Confinata per molti decenni in una posizione di marginalità, ricordata non come autrice, ma come musa ispiratrice di Jorge Luis Borges e del movimento letterario ultraista, è stata successivamente rivalutata e collocata tra le figure centrali dell'avanguardia letteraria argentina[1][2]. Prese parte all'avanguardia letteraria di Buenos Aires de...

Viticultural area in Colorado Grand ValleyWine regionVineyards below Mt. Garfield in PalisadeTypeAmerican Viticultural AreaYear established1991[1]Years of wine industry134[2]CountryUnited StatesPart ofColoradoOther regions in ColoradoWest Elks AVAClimate regionContinental, Semi-aridPrecipitation (annual average)9.06 in (230.12 mm)snow: 22 in (56 cm)[1]Soil conditionssandy Genola, Hinman, Mayfield, Mesa, Ravola, and Thoroughfare[1]Total area7...

 

Monaco ai Giochi della XXXII OlimpiadeTokyo 2020 Codice CIOMON Comitato nazionaleComité Olympique Monégasque Atleti partecipanti6 in 5 discipline Di cui uomini/donne3 - 3 PortabandieraXiaoxin Yang (tennistavolo)Quentin Antognelli (canottaggio)[1] Medagliere Posizione - 0 0 0 0 Cronologia olimpica (sommario)Giochi olimpici estivi 1920 · 1924 · 1928 · 1932 · 1936 · 1948 · 1952 · 1956 · 1960 · 1964 · 1968...

 

Indian Civil Services Indian Civil Services redirects here. The term may also refer to Indian Civil Service, the Indian civil services during the British Raj. This article is part of a series on the Politics of India Constitution and law Constitution of India Fundamental Rights, Directive Principles and Fundamental Duties of India Human rights Judicial review Taxation Uniform Civil Code Basic structure doctrine Amendment Law of India Indian criminal law Bharatiya Nyaya Sanhita Bharatiya Nagar...

Voce principale: Unione Sportiva Alessandria Calcio 1912. Alessandria Unione SportivaStagione 1932-1933Sport calcio Squadra Alessandria Allenatore Ferenc Molnár, poi Heinrich Bachmann Presidente Umberto Pugno Serie A13º posto Maggiori presenzeCampionato: Barale (34) Miglior marcatoreCampionato: Cattaneo (10) StadioCampo del Littorio 1931-1932 1933-1934 Si invita a seguire il modello di voce Questa pagina raccoglie le informazioni riguardanti l'Alessandria Unione Sportiva nelle competi...

 

  「耀州」重定向至此。關於中国古代历史上的一个行政区划,請見「耀州 (古代)」。 耀州区市辖区耀州区的地理位置坐标:34°54′50″N 108°58′23″E / 34.91378°N 108.97299°E / 34.91378; 108.97299国家 中华人民共和国隶属行政区陕西省铜川市政府駐地永安路街道面积 • 总计1,608.47 平方公里(621.03 平方英里)人口(2020年)[1] •&#...